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2. A multi-center field study of two point-of-care tests for circulating Wuchereria bancrofti antigenemia in Africa

Author

Chesnais, Cédric, Awaca-Uvon, N. P., Bolay, F. K., Boussinesq, Michel, Fischer, P. U., Gankpala, L., Meite, A., Missamou, F., Pion, Sébastien, and Weil, G. J.

Subjects
parasitic diseases
Abstract

Background The Global Programme to Eliminate Lymphatic Filariasis uses point-of-care tests for circulating filarial antigenemia (CFA) to map endemic areas and for monitoring and evaluating the success of mass drug administration (MDA) programs. We compared the performance of the reference BinaxNOW Filariasis card test (ICT, introduced in 1997) with the Alere Filariasis Test Strip (FTS, introduced in 2013) in 5 endemic study sites in Africa. Methodology The tests were compared prior to MDA in two study sites (Congo and Cote d'Ivoire) and in three sites that had received MDA (DRC and 2 sites in Liberia). Data were analyzed with regard to% positivity, % agreement, and heterogeneity. Models evaluated potential effects of age, gender, and blood microfilaria (Mf) counts in individuals and effects of endemicity and history of MDA at the village level as potential factors linked to higher sensitivity of the FTS. Lastly, we assessed relationships between CFA scores and Mf in pre- and post-MDA settings. Principal findings Paired test results were available for 3,682 individuals. Antigenemia rates were 8% and 22% higher by FTS than by ICT in pre-MDA and in post-MDA sites, respectively. FTS/ICT ratios were higher in areas with low infection rates. The probability of having microfilaremia was much higher in persons with CFA scores >1 in untreated areas. However, this was not true in post-MDA settings. Conclusions/Significance This study has provided extensive new information on the performance of the FTS compared to ICT in Africa and it has confirmed the increased sensitivity of FTS reported in prior studies. Variability in FTS/ICT was related in part to endemicity level, history of MDA, and perhaps to the medications used for MDA. These results suggest that FTS should be superior to ICT for mapping, for transmission assessment surveys, and for post-MDA surveillance.

Published
2017

3. Virus genomes reveal factors that spread and sustained the Ebola epidemic

Author

Dudas, G. (Gytis), Carvalho, L.M. (Luiz Max), Bedford, T. (Trevor), Tatem, A.J. (Andrew J.), Baele, G. (Guy), Faria, R. (Rui), Park, D.J. (Daniel J.), Ladner, J.T. (Jason T.), Arias, A., Asogun, D. (Danny), Bielejec, F. (Filip), Caddy, S.L., Cotten, M. (Matthew), D'Ambrozio, J. (Jonathan), Dellicour, S. (Simon), Di Caro, A. (Antonino), Diclaro, J.W. (Joseph W.), Duraffour, S. (Sophie), Elmore, M.J. (Michael J.), Fakoli, L.S. (Lawrence S.), Faye, O. (Ousmane), Gilbert, M.L. (Merle L.), Gevao, S.M. (Sahr M.), Gire, S. (Stephen), Gladden-Young, A. (Adrianne), Gnirke, A. (Andreas), Goba, A. (Augustine), Grant, D.S. (Donald S.), Haagmans, B.L. (Bart), Hiscox, J.A. (Julian A.), Jah, U., Kugelman, J.R. (Jeffrey R.), Liu, D. (Di), Lu, J. (Jia), Malboeuf, C.M. (Christine M.), Mate, S. (Suzanne), Matthews, D.A. (David A.), Matranga, C.B. (Christian B.), Meredith, L.W. (Luke W.), Qu, J. (James), Quick, J. (Joshua), Pas, S.D. (Suzan), Phan, M.V.T. (My V. T.), Pollakis, G. (G.), Reusken, C.B.E.M. (Chantal), Sanchez-Lockhart, M. (Mariano), Schaffner, S.F. (Stephen F.), Schieffelin, J.S. (John S.), Sealfon, R.S. (Rachel S.), Simon-Loriere, E. (Etienne), Smits, S.L. (Saskia), Stoecker, K. (Kilian), Thorne, L. (Lucy), Tobin, E.A. (Ekaete Alice), Vandi, M.A. (Mohamed A.), Watson, S.J. (Simon J.), West, K. (Kendra), Whitmer, S. (Shannon), Wiley, M.R. (Michael R.), Winnicki, S.M. (Sarah M.), Wohl, S. (Shirlee), Wölfel, R. (Roman), Yozwiak, N.L. (Nathan L.), Andersen, K.G. (Kristian G.), Blyden, S.O. (Sylvia O.), Bolay, F. (Fatorma), Carroll, M.W. (Miles W.), Dahn, B. (Bernice), Diallo, B. (Boubacar), Formenty, P. (Pierre), Fraser, C. (Christophe), Gao, G.F. (George F.), Garry, R.F. (Robert F.), Goodfellow, I. (Ian), Günther, S. (Stephan), Happi, C.T. (Christian T.), Holmes, E.C. (Edward C.), Kargbo, B. (Brima), Keïta, S. (Sakoba), Kellam, P. (Paul), Koopmans D.V.M., M.P.G. (Marion), Kuhn, J.H. (Jens H.), Loman, N.J. (Nicholas J.), Magassouba, N. (N'Faly), Naidoo, D. (Dhamari), Nichol, S.T. (Stuart T.), Nyenswah, T. (Tolbert), Palacios, G. (Gustavo), Pybus, O. (Oliver), Sabeti, P.C. (Pardis C.), Sall, A. (Amadou), Ströher, U. (Ute), Wurie, I., Suchard, M.A. (Marc), Lemey, P. (Philippe), Rambaut, A. (Andrew), Dudas, G. (Gytis), Carvalho, L.M. (Luiz Max), Bedford, T. (Trevor), Tatem, A.J. (Andrew J.), Baele, G. (Guy), Faria, R. (Rui), Park, D.J. (Daniel J.), Ladner, J.T. (Jason T.), Arias, A., Asogun, D. (Danny), Bielejec, F. (Filip), Caddy, S.L., Cotten, M. (Matthew), D'Ambrozio, J. (Jonathan), Dellicour, S. (Simon), Di Caro, A. (Antonino), Diclaro, J.W. (Joseph W.), Duraffour, S. (Sophie), Elmore, M.J. (Michael J.), Fakoli, L.S. (Lawrence S.), Faye, O. (Ousmane), Gilbert, M.L. (Merle L.), Gevao, S.M. (Sahr M.), Gire, S. (Stephen), Gladden-Young, A. (Adrianne), Gnirke, A. (Andreas), Goba, A. (Augustine), Grant, D.S. (Donald S.), Haagmans, B.L. (Bart), Hiscox, J.A. (Julian A.), Jah, U., Kugelman, J.R. (Jeffrey R.), Liu, D. (Di), Lu, J. (Jia), Malboeuf, C.M. (Christine M.), Mate, S. (Suzanne), Matthews, D.A. (David A.), Matranga, C.B. (Christian B.), Meredith, L.W. (Luke W.), Qu, J. (James), Quick, J. (Joshua), Pas, S.D. (Suzan), Phan, M.V.T. (My V. T.), Pollakis, G. (G.), Reusken, C.B.E.M. (Chantal), Sanchez-Lockhart, M. (Mariano), Schaffner, S.F. (Stephen F.), Schieffelin, J.S. (John S.), Sealfon, R.S. (Rachel S.), Simon-Loriere, E. (Etienne), Smits, S.L. (Saskia), Stoecker, K. (Kilian), Thorne, L. (Lucy), Tobin, E.A. (Ekaete Alice), Vandi, M.A. (Mohamed A.), Watson, S.J. (Simon J.), West, K. (Kendra), Whitmer, S. (Shannon), Wiley, M.R. (Michael R.), Winnicki, S.M. (Sarah M.), Wohl, S. (Shirlee), Wölfel, R. (Roman), Yozwiak, N.L. (Nathan L.), Andersen, K.G. (Kristian G.), Blyden, S.O. (Sylvia O.), Bolay, F. (Fatorma), Carroll, M.W. (Miles W.), Dahn, B. (Bernice), Diallo, B. (Boubacar), Formenty, P. (Pierre), Fraser, C. (Christophe), Gao, G.F. (George F.), Garry, R.F. (Robert F.), Goodfellow, I. (Ian), Günther, S. (Stephan), Happi, C.T. (Christian T.), Holmes, E.C. (Edward C.), Kargbo, B. (Brima), Keïta, S. (Sakoba), Kellam, P. (Paul), Koopmans D.V.M., M.P.G. (Marion), Kuhn, J.H. (Jens H.), Loman, N.J. (Nicholas J.), Magassouba, N. (N'Faly), Naidoo, D. (Dhamari), Nichol, S.T. (Stuart T.), Nyenswah, T. (Tolbert), Palacios, G. (Gustavo), Pybus, O. (Oliver), Sabeti, P.C. (Pardis C.), Sall, A. (Amadou), Ströher, U. (Ute), Wurie, I., Suchard, M.A. (Marc), Lemey, P. (Philippe), and Rambaut, A. (Andrew)

Abstract

The 2013-2016 West African epidemic caused by the Ebola virus was of unprecedented magnitude, duration and impact. Here we reconstruct the dispersal, proliferation and decline of Ebola virus throughout the region by analysing 1,610 Ebola virus genomes, which represent over 5% of the known cases. We test the association of geography, climate and demography with viral movement among administrative regions, inferring a classic 'gravity' model, with intense dispersal between larger and closer populations. Despite attenuation of international dispersal after border closures, cross-border transmission had already sown the seeds for an international epidemic, rendering these measures ineffective at curbing the epidemic. We address why the epidemic did not spread into neighbouring countries, showing that these countries were susceptible to substantial outbreaks but at lower risk of introductions. Finally, we reveal that this large epidemic was a heterogeneous and spatially dissociated collection of transmission clusters of varying size, duration and connectivity. These insights will help to inform interventions in future epidemics.

Published
2017
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4. Virus genomes reveal the factors that spread and sustained the West African Ebola epidemic

Author

Dudas, G, Carvalho, LM, Bedford, T, Tatem, A, Baele, G, Faria, N, Park, D, Ladner, J, Arias, A, Asogun, D, Bielejec, F, Caddy, S, Cotten, M, Dambrozio, J, Dellicour, S, Di Caro, A, Diclaro, J, Duraffour, S, Elmore, M, Fakoli, L, Gilbert, M, Gevao, S, Gire, S, Gladden-Young, A, Gnirke, A, Goba, A, Grant, D, Haagmans, B, Hiscox, J, Jah, U, Kargbo, B, Kugelman, J, Liu, D, Lu, J, Malboeuf, C, Mate, S, Matthews, D, Matranga, C, Meredith, L, Qu, J, Quick, J, Pas, S, Phan, MVT, Poliakis, G, Reusken, C, Sanchez-Lockhart, M, Schaffner, S, Schieffelin, J, Sealfon, R, Simon-Loriere, E, Smits, S, Stoecker, K, Thorne, L, Tobin, E, Vandi, M, Watson, S, West, K, Whitmer, S, Wiley, M, Winnicki, S, Wohl, S, Wölfel, R, Yozwiak, N, Andersen, K, Blyden, S, Bolay, F, Carroll, M, Dahn, B, Diallo, B, Formenty, P, Fraser, C, Gao, G, Garry, R, Goodfellow, I, Günther, S, Happi, C, Holmes, E, Kellam, P, Koopmans, MPG, Loman, N, Magassouba, N, Naidoo, D, Nichol, S, Nyenswah, T, Palacios, G, Pybus, O, Sabeti, P, Sall, A, Sakoba, K, Ströeher, U, Wurie, I, Suchard, M, Lemey, P, Rambaut, A, and Wellcome Trust

Subjects
viruses
Abstract

Summary The 2013-2016 epidemic of Ebola virus disease in West Africa was of unprecedented magnitude, duration and impact. Extensive collaborative sequencing projects have produced a large collection of over 1600 Ebola virus genomes, representing over 5% of known cases, unmatched for any single human epidemic. In this comprehensive analysis of this entire dataset, we reconstruct in detail the history of migration, proliferation and decline of Ebola virus throughout the region. We test the association of geography, climate, administrative boundaries, demography and culture with viral movement among 56 administrative regions. Our results show that during the outbreak viral lineages moved according to a classic ‘gravity’ model, with more intense migration between larger and more proximate population centers. Notably, we find that despite a strong attenuation of international dispersal after border closures, localized cross-border transmission beforehand had already set the seeds for an international epidemic, rendering these measures relatively ineffective in curbing the epidemic. We use this empirical evidence to address why the epidemic did not spread into neighboring countries, showing that although these regions were susceptible to developing significant outbreaks, they were also at lower risk of viral introductions. Finally, viral genome sequence data uniquely reveals this large epidemic to be a heterogeneous and spatially dissociated collection of transmission clusters of varying size, duration and connectivity. These insights will help inform approaches to intervention in such epidemics in the future.

Published
2016

7. Phase 2 Placebo-Controlled Trial of Two Vaccines to Prevent Ebola in Liberia.

Author

Kennedy, S. B., Bolay, F., Kieh, M., Grandits, G., Badio, M., Ballou, R., Eckes, R., Feinberg, M., Follmann, D., Grund, B., Gupta, S., Hensley, L., Higgs, E., Janosko, K., Johnson, M., Kateh, F., Logue, J., Marchand, J., Monath, T., and Nason, M.

Subjects
*EBOLA virus disease vaccines, *PUBLIC health, *ADENO-associated virus, *STOMATITIS, *EPIDEMICS, *THERAPEUTICS, *EBOLA virus disease prevention, *COMPARATIVE studies, *EBOLA virus disease, *FEVER, *HEADACHE, *INTRAMUSCULAR injections, *RESEARCH methodology, *MEDICAL cooperation, *MYALGIA, *POLYMERASE chain reaction, *RESEARCH, *RESEARCH funding, *RNA, *RNA viruses, *STATISTICAL sampling, *VIRAL vaccines, *VIRUSES, *EVALUATION research, *RANDOMIZED controlled trials, *BLIND experiment, *HIV seroconversion, *REVERSE transcriptase polymerase chain reaction, *EBOLA virus, *DISEASE complications
Abstract

The article presents a study on the safety and efficacy of vaccines to prevent Ebola virus disease (EVD) in Liberia. Information is provided on the chimpanzee adeno-virus 3 vaccine (ChAd3-EBO-Z) and recombinant vesicular stomatitis vaccine (rVSVAG-ZEBOV-GP) vaccines. Particular attention is given to the challenges of conducting medical research during an outbreak.

Published
2017
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8. Field Responses of Anopheles gambiae Complex (Diptera: Culicidae) in Liberia using Yeast-Generated Carbon Dioxide and Synthetic Lure-Baited Light Traps

Author

NAVY ENTOMOLOGY CENTER OF EXCELLENCE JACKSONVILLE NAS FL, Obenauer, P J, Abdel-Dayem, M S, Stoops, C A, Villinski, J T, Tageldin, R, Fahmy, N T, Diclaro II, J W, Bolay, F, NAVY ENTOMOLOGY CENTER OF EXCELLENCE JACKSONVILLE NAS FL, Obenauer, P J, Abdel-Dayem, M S, Stoops, C A, Villinski, J T, Tageldin, R, Fahmy, N T, Diclaro II, J W, and Bolay, F

Abstract

Malaria infection is a serious public health problem throughout Liberia, but vector surveillance is limited or nonexistent in remote regions of the country. To better understand the spatial and temporal distribution of malaria vectors in Liberia and to support vector and malaria activities of the Liberian Ministry of Health, a study was conducted to determine the efficacy of light traps baited with a synthetic lure and CO2 for capturing Anopheles gambiae sensu lato (Giles). Traps with a ultraviolet, light-emitting diode, and incandescent lights baited with a synthetic skin lure and CO2 combinations were evaluated at four field sites in three counties of Liberia for five consecutive nights every 8 wk during 2011. In total, 4,788 mosquitoes representing 56 species from nine genera were collected throughout the 30-wk study; An. gambiae s. l. comprised 32% and of the 148 An. gambiae s. s. collected, 85% were of the S form. A greater percentage of An. gambiae s. l. were collected in ultraviolet traps baited with a synthetic lure and CO2 compared with any other trap configuration. The influence of trap configuration on conclusions from surveillance efforts, specifically with regards to An. gambiae is discussed., Published in the Journal of Medical Entomology, v50 n4 p863-870, Jul 2013. Prepared in collaboration with the Center for Medical and Veterinary Entomology, USDA, Gainesville, FL and the U.S. Naval Medical Research Unit No. 3, Cairo, Egypt. Prepared in cooperation with the College of Food and Agricultural Sciences, King Saud University, Riyadh, Saudi Arabia, and the Liberian Institute for Biomedical Research, Monrovia, Liberia.

Published
2013

11. Possible sexual transmission of Ebola virus - Liberia, 2015

Author

Christie A, Gj, Davies-Wayne, Cordier-Lasalle T, Dj, Blackley, As, Laney, Williams DE, Sa, Shinde, Badio M, Lo T, Se, Mate, Jt, Ladner, Wiley MR, Jr, Kugelman, Gustavo Palacios, Holbrook MR, Kb, Janosko, de Wit E, van Doremalen N, Vj, Munster, Pettitt J, Rj, Schoepp, Verhenne L, Evlampidou I, Kk, Kollie, Sb, Sieh, Gasasira A, Bolay F, Fn, Kateh, Tg, Nyenswah, Km, Cock, and Centers for Disease Control and Prevention (CDC)

Subjects
Adult, Male, Unsafe Sex, Sexually Transmitted Diseases, Viral, Articles, Hemorrhagic Fever, Ebola, Middle Aged, Ebolavirus, Liberia, Disease Outbreaks, Semen, Humans, RNA, Viral, Female, Survivors
Abstract

On March 20, 2015, 30 days after the most recent confirmed Ebola Virus Disease (Ebola) patient in Liberia was isolated, Ebola was laboratory confirmed in a woman in Monrovia. The investigation identified only one epidemiologic link to Ebola: unprotected vaginal intercourse with a survivor. Published reports from previous outbreaks have demonstrated Ebola survivors can continue to harbor virus in immunologically privileged sites for a period of time after convalescence. Ebola virus has been isolated from semen as long as 82 days after symptom onset and viral RNA has been detected in semen up to 101 days after symptom onset. One instance of possible sexual transmission of Ebola has been reported, although the accompanying evidence was inconclusive. In addition, possible sexual transmission of Marburg virus, a filovirus related to Ebola, was documented in 1968. This report describes the investigation by the Government of Liberia and international response partners of the source of Liberia's latest Ebola case and discusses the public health implications of possible sexual transmission of Ebola virus. Based on information gathered in this investigation, CDC now recommends that contact with semen from male Ebola survivors be avoided until more information regarding the duration and infectiousness of viral shedding in body fluids is known. If male survivors have sex (oral, vaginal, or anal), a condom should be used correctly and consistently every time.

12. Increased Likelihood of Detecting Ebola Virus RNA in Semen by Using Sample Pelleting.

Author

Bozman CM, Fallah M, Sneller MC, Freeman C, Fakoli LS 3rd, Shobayo BI, Dighero-Kemp B, Reilly CS, Kuhn JH, Bolay F, Higgs E, and Hensley LE

Subjects
Humans, RNA, Viral, Semen, Survivors, Ebolavirus genetics, Hemorrhagic Fever, Ebola
Abstract

Ebola virus RNA can reside for months or years in semen of survivors of Ebola virus disease and is probably associated with increased risk for cryptic sexual transmission of the virus. A modified protocol resulted in increased detection of Ebola virus RNA in semen and improved disease surveillance.

Published
2021
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13. Lassa virus circulating in Liberia: a retrospective genomic characterisation.

Author

Wiley MR, Fakoli L, Letizia AG, Welch SR, Ladner JT, Prieto K, Reyes D, Espy N, Chitty JA, Pratt CB, Di Paola N, Taweh F, Williams D, Saindon J, Davis WG, Patel K, Holland M, Negrón D, Ströher U, Nichol ST, Sozhamannan S, Rollin PE, Dogba J, Nyenswah T, Bolay F, Albariño CG, Fallah M, and Palacios G

Subjects
Genome, Viral, Genomics methods, Genotype, Humans, Lassa Fever diagnosis, Lassa virus classification, Liberia epidemiology, Phylogeny, Public Health Surveillance, Lassa Fever epidemiology, Lassa Fever virology, Lassa virus genetics
Abstract

Background: An alarming rise in reported Lassa fever cases continues in west Africa. Liberia has the largest reported per capita incidence of Lassa fever cases in the region, but genomic information on the circulating strains is scarce. The aim of this study was to substantially increase the available pool of data to help foster the generation of targeted diagnostics and therapeutics., Methods: Clinical serum samples collected from 17 positive Lassa fever cases originating from Liberia (16 cases) and Guinea (one case) within the past decade were processed at the Liberian Institute for Biomedical Research using a targeted-enrichment sequencing approach, producing 17 near-complete genomes. An additional 17 Lassa virus sequences (two from Guinea, seven from Liberia, four from Nigeria, and four from Sierra Leone) were generated from viral stocks at the US Centers for Disease Control and Prevention (Atlanta, GA) from samples originating from the Mano River Union (Guinea, Liberia, and Sierra Leone) region and Nigeria. Sequences were compared with existing Lassa virus genomes and published Lassa virus assays., Findings: The 23 new Liberian Lassa virus genomes grouped within two clades (IV.A and IV.B) and were genetically divergent from those circulating elsewhere in west Africa. A time-calibrated phylogeographic analysis incorporating the new genomes suggests Liberia was the entry point of Lassa virus into the Mano River Union region and estimates the introduction to have occurred between 300-350 years ago. A high level of diversity exists between the Liberian Lassa virus genomes. Nucleotide percent difference between Liberian Lassa virus genomes ranged up to 27% in the L segment and 18% in the S segment. The commonly used Lassa Josiah-MGB assay was up to 25% divergent across the target sites when aligned to the Liberian Lassa virus genomes., Interpretation: The large amount of novel genomic diversity of Lassa virus observed in the Liberian cases emphasises the need to match deployed diagnostic capabilities with locally circulating strains and underscores the importance of evaluating cross-lineage protection in the development of vaccines and therapeutics., Funding: Defense Biological Product Assurance Office of the US Department of Defense and the Armed Forces Health Surveillance Branch and its Global Emerging Infections Surveillance and Response Section., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published
2019
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14. Single dose moxidectin versus ivermectin for Onchocerca volvulus infection in Ghana, Liberia, and the Democratic Republic of the Congo: a randomised, controlled, double-blind phase 3 trial.

Author

Opoku NO, Bakajika DK, Kanza EM, Howard H, Mambandu GL, Nyathirombo A, Nigo MM, Kasonia K, Masembe SL, Mumbere M, Kataliko K, Larbelee JP, Kpawor M, Bolay KM, Bolay F, Asare S, Attah SK, Olipoh G, Vaillant M, Halleux CM, and Kuesel AC

Subjects
Adolescent, Animals, Anthelmintics adverse effects, Democratic Republic of the Congo epidemiology, Double-Blind Method, Endemic Diseases, Female, Ghana epidemiology, Humans, Ivermectin adverse effects, Liberia epidemiology, Macrolides adverse effects, Male, Microfilariae drug effects, Onchocerciasis epidemiology, Parasite Load, Skin parasitology, Anthelmintics administration & dosage, Ivermectin administration & dosage, Macrolides administration & dosage, Onchocerca volvulus, Onchocerciasis drug therapy
Abstract

Background: The morbidity and socioeconomic effects of onchocerciasis, a parasitic disease that is primarily endemic in sub-Saharan Africa, have motivated large morbidity and transmission control programmes. Annual community-directed ivermectin treatment has substantially reduced prevalence. Elimination requires intensified efforts, including more efficacious treatments. We compared parasitological efficacy and safety of moxidectin and ivermectin., Methods: This double-blind, parallel group, superiority trial was done in four sites in Ghana, Liberia, and the Democratic Republic of the Congo. We enrolled participants (aged ≥12 years) with at least 10 Onchocerca volvulus microfilariae per mg skin who were not co-infected with Loa loa or lymphatic filariasis microfilaraemic. Participants were randomly allocated, stratified by sex and level of infection, to receive a single oral dose of 8 mg moxidectin or 150 μg/kg ivermectin as overencapsulated oral tablets. The primary efficacy outcome was skin microfilariae density 12 months post treatment. We used a mixed-effects model to test the hypothesis that the primary efficacy outcome in the moxidectin group was 50% or less than that in the ivermectin group. The primary efficacy analysis population were all participants who received the study drug and completed 12-month follow-up (modified intention to treat). This study is registered with ClinicalTrials.gov, number NCT00790998., Findings: Between April 22, 2009, and Jan 23, 2011, we enrolled and allocated 998 participants to moxidectin and 501 participants to ivermectin. 978 received moxidectin and 494 ivermectin, of which 947 and 480 were included in primary efficacy outcome analyses. At 12 months, skin microfilarial density (microfilariae per mg of skin) was lower in the moxidectin group (adjusted geometric mean 0·6 [95% CI 0·3-1·0]) than in the ivermectin group (4·5 [3·5-5·9]; difference 3·9 [3·2-4·9], p<0·0001; treatment difference 86%). Mazzotti (ie, efficacy-related) reactions occurred in 967 (99%) of 978 moxidectin-treated participants and in 478 (97%) of 494 ivermectin-treated participants, including ocular reactions (moxidectin 113 [12%] participants and ivermectin 47 [10%] participants), laboratory reactions (788 [81%] and 415 [84%]), and clinical reactions (944 [97%] and 446 [90%]). No serious adverse events were considered to be related to treatment., Interpretation: Skin microfilarial loads (ie, parasite transmission reservoir) are lower after moxidectin treatment than after ivermectin treatment. Moxidectin would therefore be expected to reduce parasite transmission between treatment rounds more than ivermectin could, thus accelerating progress towards elimination., Funding: UNICEF/UNDP/World Bank/WHO Special Programme for Research and Training in Tropical Diseases., (© 2018 World Health Organization; licensee Elsevier. This is an Open Access article published under the CC BY 3.0 IGO license which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. In any use of this article, there should be no suggestion that WHO endorses any specific organisation, products or services. The use of the WHO logo is not permitted. This notice should be preserved along with the article's original URL.)

Published
2018
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15. Cross-Border Transmission of Ebola Virus as the Cause of a Resurgent Outbreak in Liberia in April 2016.

Author

Mate SE, Wiley MR, Ladner JT, Dokubo EK, Fakoli L, Fallah M, Nyenswah TG, DiClaro JW, Deboer JT, Williams DE, Bolay F, and Palacios G

Subjects
Emigration and Immigration, Genome, Viral, Guinea epidemiology, Hemorrhagic Fever, Ebola virology, Humans, Liberia epidemiology, Disease Outbreaks, Ebolavirus genetics, Hemorrhagic Fever, Ebola epidemiology
Published
2018
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16. Persistence of Ebola virus after the end of widespread transmission in Liberia: an outbreak report.

Author

Dokubo EK, Wendland A, Mate SE, Ladner JT, Hamblion EL, Raftery P, Blackley DJ, Laney AS, Mahmoud N, Wayne-Davies G, Hensley L, Stavale E, Fakoli L, Gregory C, Chen TH, Koryon A, Roth Allen D, Mann J, Hickey A, Saindon J, Badini M, Baller A, Clement P, Bolay F, Wapoe Y, Wiley MR, Logue J, Dighero-Kemp B, Higgs E, Gasasira A, Williams DE, Dahn B, Kateh F, Nyenswah T, Palacios G, and Fallah MP

Subjects
Adolescent, Adult, Aged, Aged, 80 and over, Child, Child, Preschool, Female, Humans, Infant, Liberia epidemiology, Male, Middle Aged, Disease Outbreaks prevention & control, Disease Outbreaks statistics & numerical data, Epidemics prevention & control, Epidemics statistics & numerical data, Hemorrhagic Fever, Ebola epidemiology, Hemorrhagic Fever, Ebola prevention & control, Hemorrhagic Fever, Ebola transmission
Abstract

Background: Outbreak response efforts for the 2014-15 Ebola virus disease epidemic in west Africa brought widespread transmission to an end. However, subsequent clusters of infection have occurred in the region. An Ebola virus disease cluster in Liberia in November, 2015, that was identified after a 15-year-old boy tested positive for Ebola virus infection in Monrovia, raised the possibility of transmission from a persistently infected individual., Methods: Case investigations were done to ascertain previous contact with cases of Ebola virus disease or infection with Ebola virus. Molecular investigations on blood samples explored a potential linkage between Ebola virus isolated from cases in this November, 2015, cluster and epidemiologically linked cases from the 2014-15 west African outbreak, according to the national case database., Findings: The cluster investigated was the family of the index case (mother, father, three siblings). Ebola virus genomes assembled from two cases in the November, 2015, cluster, and an epidemiologically linked Ebola virus disease case in July, 2014, were phylogenetically related within the LB5 sublineage that circulated in Liberia starting around August, 2014. Partial genomes from two additional individuals, one from each cluster, were also consistent with placement in the LB5 sublineage. Sequencing data indicate infection with a lineage of the virus from a former transmission chain in the country. Based on serology and epidemiological and genomic data, the most plausible scenario is that a female case in the November, 2015, cluster survived Ebola virus disease in 2014, had viral persistence or recurrent disease, and transmitted the virus to three family members a year later., Interpretation: Investigation of the source of infection for the November, 2015, cluster provides evidence of Ebola virus persistence and highlights the risk for outbreaks after interruption of active transmission. These findings underscore the need for focused prevention efforts among survivors and sustained capacity to rapidly detect and respond to new Ebola virus disease cases to prevent recurrence of a widespread outbreak., Funding: US Centers for Disease Control and Prevention, Defense Threat Reduction Agency, and WHO., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published
2018
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17. Virus genomes reveal factors that spread and sustained the Ebola epidemic.

Author

Dudas G, Carvalho LM, Bedford T, Tatem AJ, Baele G, Faria NR, Park DJ, Ladner JT, Arias A, Asogun D, Bielejec F, Caddy SL, Cotten M, D'Ambrozio J, Dellicour S, Di Caro A, Diclaro JW, Duraffour S, Elmore MJ, Fakoli LS, Faye O, Gilbert ML, Gevao SM, Gire S, Gladden-Young A, Gnirke A, Goba A, Grant DS, Haagmans BL, Hiscox JA, Jah U, Kugelman JR, Liu D, Lu J, Malboeuf CM, Mate S, Matthews DA, Matranga CB, Meredith LW, Qu J, Quick J, Pas SD, Phan MVT, Pollakis G, Reusken CB, Sanchez-Lockhart M, Schaffner SF, Schieffelin JS, Sealfon RS, Simon-Loriere E, Smits SL, Stoecker K, Thorne L, Tobin EA, Vandi MA, Watson SJ, West K, Whitmer S, Wiley MR, Winnicki SM, Wohl S, Wölfel R, Yozwiak NL, Andersen KG, Blyden SO, Bolay F, Carroll MW, Dahn B, Diallo B, Formenty P, Fraser C, Gao GF, Garry RF, Goodfellow I, Günther S, Happi CT, Holmes EC, Kargbo B, Keïta S, Kellam P, Koopmans MPG, Kuhn JH, Loman NJ, Magassouba N, Naidoo D, Nichol ST, Nyenswah T, Palacios G, Pybus OG, Sabeti PC, Sall A, Ströher U, Wurie I, Suchard MA, Lemey P, and Rambaut A

Subjects
Climate, Disease Outbreaks statistics & numerical data, Ebolavirus isolation & purification, Geography, Hemorrhagic Fever, Ebola epidemiology, Humans, Internationality, Linear Models, Molecular Epidemiology, Phylogeny, Travel legislation & jurisprudence, Travel statistics & numerical data, Ebolavirus genetics, Ebolavirus physiology, Genome, Viral genetics, Hemorrhagic Fever, Ebola transmission, Hemorrhagic Fever, Ebola virology
Abstract

The 2013-2016 West African epidemic caused by the Ebola virus was of unprecedented magnitude, duration and impact. Here we reconstruct the dispersal, proliferation and decline of Ebola virus throughout the region by analysing 1,610 Ebola virus genomes, which represent over 5% of the known cases. We test the association of geography, climate and demography with viral movement among administrative regions, inferring a classic 'gravity' model, with intense dispersal between larger and closer populations. Despite attenuation of international dispersal after border closures, cross-border transmission had already sown the seeds for an international epidemic, rendering these measures ineffective at curbing the epidemic. We address why the epidemic did not spread into neighbouring countries, showing that these countries were susceptible to substantial outbreaks but at lower risk of introductions. Finally, we reveal that this large epidemic was a heterogeneous and spatially dissociated collection of transmission clusters of varying size, duration and connectivity. These insights will help to inform interventions in future epidemics.

Published
2017
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18. Assessment and Optimization of the GeneXpert Diagnostic Platform for Detection of Ebola Virus RNA in Seminal Fluid.

Author

Pettitt J, Higgs E, Fallah M, Nason M, Stavale E, Marchand J, Reilly C, Jensen K, Dighero-Kemp B, Tuznik K, Logue J, Bolay F, and Hensley L

Subjects
Democratic Republic of the Congo, Hemorrhagic Fever, Ebola blood, Humans, Liberia, Limit of Detection, Male, Pilot Projects, RNA, Viral blood, Sensitivity and Specificity, Survivors, Ebolavirus isolation & purification, Hemorrhagic Fever, Ebola diagnosis, RNA, Viral isolation & purification, Real-Time Polymerase Chain Reaction methods, Semen virology
Abstract

Recent studies have suggested that Ebola virus (EBOV) ribonucleic acid (RNA) potentially present in the semen of a large number of survivors of Ebola virus disease (EVD) in Western Africa may contribute to sexual transmission of EVD and generate new clusters of cases in regions previously declared EVD-free. These findings drive the immediate need for a reliable, rapid, user-friendly assay for detection of EBOV RNA in semen that is deployable to multiple sites across Western Africa. In this study, we optimized the Xpert EBOV assay for semen samples by adding dithiothreitol. Compared to the assays currently in use in Liberia (including Ebola Zaire Target 1, major groove binder real-time-polymerase chain reaction assays, and original Xpert EBOV assay), the modified Xpert EBOV assay demonstrated greater sensitivity than the comparator assays. Thus, the modified Xpert EBOV assay is optimal for large-scale monitoring of EBOV RNA persistence in male survivors., (Published by Oxford University Press for the Infectious Diseases Society of America 2016. This work is written by (a) US Government employee(s) and is in the public domain in the US.)

Published
2017
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19. Reduced evolutionary rate in reemerged Ebola virus transmission chains.

Author

Blackley DJ, Wiley MR, Ladner JT, Fallah M, Lo T, Gilbert ML, Gregory C, D'ambrozio J, Coulter S, Mate S, Balogun Z, Kugelman J, Nwachukwu W, Prieto K, Yeiah A, Amegashie F, Kearney B, Wisniewski M, Saindon J, Schroth G, Fakoli L, Diclaro JW 2nd, Kuhn JH, Hensley LE, Jahrling PB, Ströher U, Nichol ST, Massaquoi M, Kateh F, Clement P, Gasasira A, Bolay F, Monroe SS, Rambaut A, Sanchez-Lockhart M, Scott Laney A, Nyenswah T, Christie A, and Palacios G

Subjects
Disease Outbreaks, Ebolavirus genetics, Genome, Viral genetics, Hemorrhagic Fever, Ebola genetics, Hemorrhagic Fever, Ebola virology, Humans, Liberia, Ebolavirus pathogenicity, Hemorrhagic Fever, Ebola epidemiology, Hemorrhagic Fever, Ebola transmission
Abstract

On 29 June 2015, Liberia's respite from Ebola virus disease (EVD) was interrupted for the second time by a renewed outbreak ("flare-up") of seven confirmed cases. We demonstrate that, similar to the March 2015 flare-up associated with sexual transmission, this new flare-up was a reemergence of a Liberian transmission chain originating from a persistently infected source rather than a reintroduction from a reservoir or a neighboring country with active transmission. Although distinct, Ebola virus (EBOV) genomes from both flare-ups exhibit significantly low genetic divergence, indicating a reduced rate of EBOV evolution during persistent infection. Using this rate of change as a signature, we identified two additional EVD clusters that possibly arose from persistently infected sources. These findings highlight the risk of EVD flare-ups even after an outbreak is declared over.

Published
2016
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20. Molecular Evidence of Sexual Transmission of Ebola Virus.

Author

Mate SE, Kugelman JR, Nyenswah TG, Ladner JT, Wiley MR, Cordier-Lassalle T, Christie A, Schroth GP, Gross SM, Davies-Wayne GJ, Shinde SA, Murugan R, Sieh SB, Badio M, Fakoli L, Taweh F, de Wit E, van Doremalen N, Munster VJ, Pettitt J, Prieto K, Humrighouse BW, Ströher U, DiClaro JW, Hensley LE, Schoepp RJ, Safronetz D, Fair J, Kuhn JH, Blackley DJ, Laney AS, Williams DE, Lo T, Gasasira A, Nichol ST, Formenty P, Kateh FN, De Cock KM, Bolay F, Sanchez-Lockhart M, and Palacios G

Subjects
Adult, Coitus, Ebolavirus isolation & purification, Female, Genome, Viral, Hemorrhagic Fever, Ebola virology, Humans, Liberia, Male, RNA, Viral blood, Reverse Transcriptase Polymerase Chain Reaction, Unsafe Sex, Ebolavirus genetics, Hemorrhagic Fever, Ebola transmission, Semen virology
Abstract

A suspected case of sexual transmission from a male survivor of Ebola virus disease (EVD) to his female partner (the patient in this report) occurred in Liberia in March 2015. Ebola virus (EBOV) genomes assembled from blood samples from the patient and a semen sample from the survivor were consistent with direct transmission. The genomes shared three substitutions that were absent from all other Western African EBOV sequences and that were distinct from the last documented transmission chain in Liberia before this case. Combined with epidemiologic data, the genomic analysis provides evidence of sexual transmission of EBOV and evidence of the persistence of infective EBOV in semen for 179 days or more after the onset of EVD. (Funded by the Defense Threat Reduction Agency and others.).

Published
2015
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21. Possible sexual transmission of Ebola virus - Liberia, 2015.

Author

Christie A, Davies-Wayne GJ, Cordier-Lassalle T, Blackley DJ, Laney AS, Williams DE, Shinde SA, Badio M, Lo T, Mate SE, Ladner JT, Wiley MR, Kugelman JR, Palacios G, Holbrook MR, Janosko KB, de Wit E, van Doremalen N, Munster VJ, Pettitt J, Schoepp RJ, Verhenne L, Evlampidou I, Kollie KK, Sieh SB, Gasasira A, Bolay F, Kateh FN, Nyenswah TG, and De Cock KM

Subjects
Adult, Disease Outbreaks, Female, Hemorrhagic Fever, Ebola epidemiology, Humans, Liberia epidemiology, Male, Middle Aged, RNA, Viral, Semen virology, Survivors, Unsafe Sex, Ebolavirus isolation & purification, Hemorrhagic Fever, Ebola diagnosis, Hemorrhagic Fever, Ebola transmission, Sexually Transmitted Diseases, Viral
Abstract

On March 20, 2015, 30 days after the most recent confirmed Ebola Virus Disease (Ebola) patient in Liberia was isolated, Ebola was laboratory confirmed in a woman in Monrovia. The investigation identified only one epidemiologic link to Ebola: unprotected vaginal intercourse with a survivor. Published reports from previous outbreaks have demonstrated Ebola survivors can continue to harbor virus in immunologically privileged sites for a period of time after convalescence. Ebola virus has been isolated from semen as long as 82 days after symptom onset and viral RNA has been detected in semen up to 101 days after symptom onset. One instance of possible sexual transmission of Ebola has been reported, although the accompanying evidence was inconclusive. In addition, possible sexual transmission of Marburg virus, a filovirus related to Ebola, was documented in 1968. This report describes the investigation by the Government of Liberia and international response partners of the source of Liberia's latest Ebola case and discusses the public health implications of possible sexual transmission of Ebola virus. Based on information gathered in this investigation, CDC now recommends that contact with semen from male Ebola survivors be avoided until more information regarding the duration and infectiousness of viral shedding in body fluids is known. If male survivors have sex (oral, vaginal, or anal), a condom should be used correctly and consistently every time.

Published
2015

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