Heterogeneities in the case fatality ratio in the West African Ebola outbreak 2013–2016

Garske, Tini; Cori, Anne; Ariyarajah, Archchun; Blake, Isobel M.; Dorigatti, Ilaria; Eckmanns, Tim; Fraser, Christophe; Hinsley, Wes; Jombart, Thibaut; Mills, Harriet L.; Nedjati-Gilani, Gemma; Newton, Emily; Nouvellet, Pierre; Perkins, Devin; Riley, Steven; Schumacher, Dirk; Shah, Anita; Kerkhove, Maria D. Van; Dye, Christopher; Ferguson, Neil; Donnelly, Christl A.

doi:10.1098/rstb.2016.0308

Cited by 101 publications

(102 citation statements)

References 31 publications

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“…The high mobility of the population across borders and closer proximity to urban centers, even when living remotely, will probably have increased transmission frequency in the three heavily affected countries (Coltart et al, 2017; WHO Ebola Response Team et al, 2016). Higher survival rates of patients and virus persistence in convalescents may have further increased the chances for transmission (Garske et al, 2017; Sissoko et al, 2017a, 2017b). These are only a few examples of many more that should be considered and investigated.…”

Section: Discussionmentioning

confidence: 99%

Recently Identified Mutations in the Ebola Virus-Makona Genome Do Not Alter Pathogenicity in Animal Models

et al. 2018

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Summary Ebola virus (EBOV), isolate Makona, the causative agent of the West African EBOV epidemic, has been the subject of numerous investigations to determine the genetic diversity and its potential implication for virus biology, pathogenicity, and transmissibility. Despite various mutations that have emerged over time through multiple human-to-human transmission chains, their biological relevance remains questionable. Recently, mutations in the glycoprotein GP and polymerase L, which emerged and stabilized early during the outbreak, have been associated with improved viral fitness in cell culture. Here, we infected mice and rhesus macaques with EBOV-Makona isolates carrying or lacking those mutations. Surprisingly, all isolates behaved very similarly independent of the genotype, causing severe or lethal disease in mice and macaques, respectively. Likewise, we could not detect any evidence for differences in virus shedding. Thus, no specific biological phenotype could be associated with these EBOV-Makona mutations in two animal models.

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Section: Discussionmentioning

confidence: 99%

Recently Identified Mutations in the Ebola Virus-Makona Genome Do Not Alter Pathogenicity in Animal Models

et al. 2018

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“…Although some experts had maintained that EVD was a perennial threat of significant public health concern [16], it had largely come to be regarded as a minimal threat that was confined to remote populations and of very limited outbreak potential, insignificant in comparison to other infectious diseases [17,18]. Ultimately, however, approximately 30,000 cases were reported during the west Africa outbreak [19] ( Figure 4B)two orders of magnitude greater than any preceding outbreak and over 20 times the total of all previously known casesand at 888 days in duration it was nearly four times longer than any previous outbreak (Figures 1 and 4A). EVD patients from the outbreak eventually reached 15 different countries spanning three continents as part of transmission chains or for medical treatment (Table 1), with Guinea, Liberia, and Sierra Leone at the epicenter.…”

Section: The West Africa Evd Outbreak 2013-2016mentioning

confidence: 99%

Delayed recognition of Ebola virus disease is associated with longer and larger outbreaks

Matson

Chertow

Munster

2020

Emerging Microbes & Infections

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The average time required to detect an Ebola virus disease (EVD) outbreak following spillover of Ebola virus (EBOV) to a primary human case has remained essentially unchanged for over 40 years, with some of the longest delays in detection occurring in recent decades. In this review, our aim was to examine the relationship between delays in detection of EVD and the duration and size of outbreaks, and we report that longer delays are associated with longer and larger EVD outbreaks. Historically, EVD outbreaks have typically been comprised of less than 100 cases (median = 60) and have lasted less than 4 months (median = 118 days). The ongoing outbreak in Democratic Republic of the Congo, together with the 2013-2016 west Africa outbreak, are stark outliers amidst these trends and had two of the longest delays in detection on record. While significant progress has been made in the development of EVD countermeasures, implementation during EVD outbreaks is problematic. Thus, EVD surveillance must be improved by the broad deployment of modern diagnostic tools, as prompt recognition of EVD has the potential to stem early transmission and ultimately limit the duration and size of outbreaks.

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“…Some heterogeneity in severity and transmissibility could be identified (e.g. by age and viraemia [7,10,116,125,[130][131][132]), but other types of heterogeneity could not be assessed. For example, it was not possible to compare the CFR between hospitalized and non-hospitalized cases, because of biases in the way cases were recorded in the line-list [28].…”

Section: Successes and Challenges In Data Collection And Analyses Durmentioning

confidence: 99%

Key data for outbreak evaluation: building on the Ebola experience

Cori

Donnelly

Dorigatti

et al. 2017

Phil. Trans. R. Soc. B

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Following the detection of an infectious disease outbreak, rapid epidemiological assessment is critical for guiding an effective public health response. To understand the transmission dynamics and potential impact of an outbreak, several types of data are necessary. Here we build on experience gained in the West African Ebola epidemic and prior emerging infectious disease outbreaks to set out a checklist of data needed to: (1) quantify severity and transmissibility; (2) characterize heterogeneities in transmission and their determinants; and (3) assess the effectiveness of different interventions. We differentiate data needs into individual-level data (e.g. a detailed list of reported cases), exposure data (e.g. identifying where/how cases may have been infected) and population-level data (e.g. size/demographics of the population(s) affected and when/where interventions were implemented). A remarkable amount of individual-level and exposure data was collected during the West African Ebola epidemic, which allowed the assessment of (1) and (2). However, gaps in population-level data (particularly around which interventions were applied when and where) posed challenges to the assessment of (3). Here we highlight recurrent data issues, give practical suggestions for addressing these issues and discuss priorities for improvements in data collection in future outbreaks.This article is part of the themed issue ‘The 2013–2016 West African Ebola epidemic: data, decision-making and disease control’.

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Heterogeneities in the case fatality ratio in the West African Ebola outbreak 2013–2016

Cited by 101 publications

References 31 publications

Recently Identified Mutations in the Ebola Virus-Makona Genome Do Not Alter Pathogenicity in Animal Models

Recently Identified Mutations in the Ebola Virus-Makona Genome Do Not Alter Pathogenicity in Animal Models

Delayed recognition of Ebola virus disease is associated with longer and larger outbreaks

Key data for outbreak evaluation: building on the Ebola experience

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