WHO, UK Wellcome Trust, the UK Government through the Department of International Development, Médecins Sans Frontières, Norwegian Ministry of Foreign Affairs (through the Research Council of Norway's GLOBVAC programme), and the Canadian Government (through the Public Health Agency of Canada, Canadian Institutes of Health Research, International Development Research Centre and Department of Foreign Affairs, Trade and Development).

The results add weight to the interim assessment that rVSV-ZEBOV offers substantial protection against Ebola virus disease, with no cases among vaccinated individuals from day 10 after vaccination in both randomised and non-randomised clusters.

In the randomised part of the trial we identified 4539 contacts and contacts of contacts in 51 clusters randomly assigned to immediate vaccination (of whom 3232 were eligible, 2151 consented, and 2119 were immediately vaccinated) and 4557 contacts and contacts of contacts in 47 clusters randomly assigned to delayed vaccination (of whom 3096 were eligible, 2539 consented, and 2041 were vaccinated 21 days after randomisation). No cases of Ebola virus disease occurred 10 days or more after randomisation among randomly assigned contacts and contacts of contacts vaccinated in immediate clusters versus 16 cases (7 clusters affected) among all eligible individuals in delayed clusters. Vaccine efficacy was 100% (95% CI 68·9–100·0, p=0·0045), and the calculated intraclass correlation coefficient was 0·035. Additionally, we defined 19 non-randomised clusters in which we enumerated 2745 contacts and contacts of contacts, 2006 of whom were eligible and 1677 were immediately vaccinated, including 194 children. The evidence from all 117 clusters showed that no cases of Ebola virus disease occurred 10 days or more after randomisation among all immediately vaccinated contacts and contacts of contacts versus 23 cases (11 clusters affected) among all eligible contacts and contacts of contacts in delayed plus all eligible contacts and contacts of contacts never vaccinated in immediate clusters. The estimated vaccine efficacy here was 100% (95% CI 79·3–100·0, p=0·0033). 52% of contacts and contacts of contacts assigned to immediate vaccination and in non-randomised clusters received the vaccine immediately; vaccination protected both vaccinated and unvaccinated people in those clusters. 5837 individuals in total received the vaccine (5643 adults and 194 children), and all vaccinees were followed up for 84 days. 3149 (53·9%) of 5837 individuals reported at least one adverse event in the 14 days after vaccination; these were typically mild (87·5% of all 7211 adverse events). Headache (1832 [25·4%]), fatigue (1361 [18·9%]), and muscle pain (942 [13·1%]) were the most commonly reported adverse events in this period across all age groups. 80 serious adverse events were identified, of which two were judged to be related to vaccination (one febrile reaction and one anaphylaxis) and one possibly related (influenza-like illness); all three recovered without sequelae.

We did an open-label, cluster-randomised ring vaccination trial (Ebola ça Suffit!) in the communities of Conakry and eight surrounding prefectures in the Basse-Guinée region of Guinea, and in Tomkolili and Bombali in Sierra Leone. We assessed the efficacy of a single intramuscular dose of rVSV-ZEBOV (2×10 7 plaque-forming units administered in the deltoid muscle) in the prevention of laboratory confirmed Ebola virus disease. After confirmation of a case of Ebola virus disease, we definitively enumerated on a list a ring (cluster) of all their contacts and contacts of contacts including named contacts and contacts of contacts who were absent at the time of the trial team visit. The list was archived, then we randomly assigned clusters (1:1) to either immediate vaccination or delayed vaccination (21 days later) of all eligible individuals (eg, those aged ≥18 years and not pregnant, breastfeeding, or severely ill). An independent statistician generated the assignment sequence using block randomisation with randomly varying blocks, stratified by location (urban vs rural) and size of rings (≤20 individuals vs >20 individuals). Ebola response teams and laboratory workers were unaware of assignments. After a recommendation by an independent data and safety monitoring board, randomisation was stopped and immediate vaccination was also offered to children aged 6–17 years and all identified rings. The prespecified primary outcome was a laboratory confirmed case of Ebola virus disease with onset 10 days or more from randomisation. The primary analysis compared the incidence of Ebola virus disease in eligible and vaccinated individuals assigned to immediate vaccination versus eligible contacts and contacts of contacts assigned to delayed vaccination. This trial is registered with the Pan African Clinical Trials Registry, number PACTR201503001057193.

rVSV-ZEBOV is a recombinant, replication competent vesicular stomatitis virus-based candidate vaccine expressing a surface glycoprotein of Zaire Ebolavirus. We tested the effect of rVSV-ZEBOV in preventing Ebola virus disease in contacts and contacts of contacts of recently confirmed cases in Guinea, west Africa.

We used a novel trial design, which had a high probability of generating evidence on the individual and cluster-level effects of the vaccine despite the low and decreasing incidence of Ebola virus disease. These results indicate that rVSV-ZEBOV is safe and effective in averting Ebola virus disease when added to established control measures as a ring vaccination approach. Ring vaccination trials might have application in the assessment of other vaccine candidates in epidemics of other viral haemorrhagic fevers or other emerging infectious diseases.

Ebola Ça Suffit used a novel trial design based on identification of people at risk around a newly confirmed case of Ebola virus disease (contacts and contacts of contacts) and ring vaccination to improve the prospect of generating robust evidence on the effects of the vaccine despite the low and decreasing incidence of Ebola virus disease. Individuals were either randomly assigned to immediate vaccination or delayed vaccination, or not randomly assigned (and received immediate vaccination). Interim analysis suggested that rVSV-ZEBOV offered very high protection, leading to the delayed-vaccination arm being discontinued. Final data from all trial clusters (randomised and non-randomised, with children included in the non-randomised group) showed that at 10 days or more after randomisation, there were no cases of Ebola virus disease among immediately vaccinated contacts and contacts of contacts; ie, 100% protection. Adverse events data indicated no safety concerns in adults or children.

There are currently no licensed vaccines for preventing Ebola virus disease or other filovirus infections. The rVSV-ZEBOV candidate vaccine has been reported to be protective in challenge models in several non-human species. We searched Medline and EMBASE without language restrictions for articles published from January, 1990, to July 20, 2015, to identify any published phase 3 clinical trials assessing the efficacy of Ebola vaccines, using the search terms “Ebola virus”, “filovirus”, “prophylaxis”, “vaccine”, and “clinical trials”. The rVSV-ZEBOV vaccine has been studied in phase 1 and phase 2 studies, which have documented its immunogenicity and safety profile. To our knowledge, ours is the only phase 3 trial of this vaccine in west Africa that has reported results, and no trial until now has used the ring vaccination cluster-randomised design. Therefore, we could not do a detailed systematic review at this point in time.

We therefore undertook Ebola ça Suffit! (translated as “Ebola that's enough!”), a ring vaccination phase 3 efficacy trial in Guinea whose primary objective was to assess the efficacy of the rVSV-ZEBOV vaccine for the prevention of Ebola virus disease in human beings (the ring vaccination approach was inspired by the surveillance-containment strategy that led to smallpox eradication).Preliminary results indicated 100% vaccine efficacy (95% CI 74·7–100·0) at interim analysis, after which the delayed-vaccination arm was discontinued.Here, we present the final results of the trial.

Since the Ebola virus was first identified in 1976, sporadic outbreaks of Ebola virus disease have been reported in Africa, each causing high mortality.No vaccine is currently licensed for preventing Ebola virus disease or other filovirus infections. The 2013–16 outbreak of Ebola virus disease in west Africahighlighted the need to produce and assess a safe and effective Ebola vaccine for human beings.One promising vaccine candidate,the recombinant, replication-competent, vesicular stomatitis virus-based vaccine expressing the glycoprotein of a Zaire Ebolavirus (rVSV-ZEBOV), is protective in challenge models in several animal species,including mice, hamsters, guinea pigs, and non-human primates.A single dose completely protected non-human primates against high-dose challenge (around 1000 particle-forming units) when administered between 7 and 31 days pre-challengeand partly protected non-human primates when administered from 3 days beforeto 24 h after challenge with the Makona strain responsible for the west African epidemic.

Funders other than the institutions of the authors had no role in the design of the study, data collection, data analysis, data interpretation, or writing of the report. The authors contributed to study design and data interpretation. The corresponding author had full access to all the data in the study and had final responsibility for the decision to submit for publication.

Similar to the interim analysis, if no cases of Ebola virus disease occurred in one group, we derived a 95% CI for the vaccine effect by fitting a β-binomial distribution to the cluster-level numerators and denominators and used an inverted likelihood ratio test to identify the lower bound for vaccine effect. For comparisons in which cases of Ebola virus disease occurred in both groups, we fitted a Cox proportional hazards model using a cluster-level frailty term to adjust for clustering within rings.We used Fisher's exact test to compare the proportions of clusters with at least one event across the two trial groups. The primary analysis was per protocol. We did all analyses in R, version 3.3.1.We received comments on the protocol and statistical analysis plan from an independent scientific advisory group. Independent clinical monitors validated 100% of the case report forms and an independent auditor assessed the study site, field activities, and supporting documentation. This trial is registered with the Pan African Clinical Trials Registry, number PACTR201503001057193.

We also analysed the evidence from all clusters, including data from randomised and non-randomised clusters. For all clusters, we compared the incidence of Ebola virus disease in: all vaccinated in immediate versus all contacts and contacts of contacts who were eligible in delayed plus all contacts and contacts of contacts who were eligible but never vaccinated in immediate; all contacts and contacts of contacts in immediate versus all contacts and contacts of contacts in delayed and; all vaccinated in immediate versus all eligible but never vaccinated in immediate. Additionally, we characterised the risk of Ebola exposure and participant characteristics for all the groups being compared.

The sample size calculation is described elsewhere.We analysed outcomes at the cluster level rather than individual level using the cumulative incidence of valid outcomes for each cluster. Additional to the planned analyses,and to address external suggestions on our interim analysis reportwe did further analyses of the randomised data. For the randomised evidence, we compared the incidence of Ebola virus disease in: 1) all vaccinated in immediate versus all contacts and contacts of contacts eligible and who consented on day 0 visit in delayed; 2) all vaccinated in immediate versus all contacts and contacts of contacts eligible in delayed; 3) all contacts and contacts of contacts eligible in immediate versus all contacts and contacts of contacts eligible in delayed; and 4) all contacts and contacts of contacts in immediate versus all contacts and contacts of contacts in delayed.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

A priori, we defined that only cases of Ebola virus disease with an onset 10 or more days from randomisation were valid outcomes for the trial.This was done to account for the incubation period of Ebola virus disease,the time between onset of symptoms and laboratory confirmation and the unknown period between vaccination and a vaccine-induced protective immune response (lag period).Additionally, vaccinated cases of Ebola virus disease with an onset of more than 31 days after random assignment were censored to account for vaccination in the delayed clusters on day 21.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

Local laboratories of the Ebola surveillance system confirmed cases by either detection of virus RNA by reverse transcriptase-PCR or detection of IgM antibodies directed against Ebola virus.If available to us, aliquots of samples were retested at the European Mobile Laboratory using the RealStar Zaire Ebolavirus reverse transcriptase-PCR kit 1.0. All index cases and secondary cases of Ebola virus disease occurring in the clusters were documented using laboratory results, case investigation forms and information on chains of transmission developed independently by the national surveillance team and, if needed, supplemented with information collected by trial personnel.

The primary outcome was a laboratory confirmed case of Ebola virus disease, defined as any probable or suspected case from whom a blood sample was taken and laboratory confirmed as positive for Ebola virus; or any deceased individual with probable Ebola virus disease, from whom a post-mortem sample taken within 48 h after death was laboratory confirmed as positive for Ebola virus disease.In our secondary objectives, we analysed the vaccine effect on deaths due to Ebola virus disease. A prespecified secondary analysis examined the overall ring vaccination effectiveness in protecting all contacts and contacts of contacts in the randomised clusters (including unvaccinated cluster members) although the trial was not powered to measure population level effects.

To assess safety, vaccinees were observed for 30 min post-vaccination and at home visits on days 3, 14, 21, 42, 63, and 84. The possible causal relationship of any adverse event to vaccination was judged by the study physicians and reported to the DSMB. Vaccinees were provided with acetaminophen or ibuprofen for the management or prevention of post-vaccination fever.

The rVSV-ZEBOV vaccine (Merck Sharp & Dohme, Kenilworth, NJ, USA) was selected for the trial according to a framework developed by an independent group of experts.All vaccinees received one dose of 2 × 10plaque-forming units of the rVSV-ZEBOV vaccine intramuscularly in the deltoid muscle.

Within 1–2 days of confirmation of a new case of Ebola virus disease, our social communication teams visited the area of residence of the case and sought the communities' consent for the trial team to enumerate a new cluster. A second team enumerated the cluster list of contacts and contacts of contacts. This list was then stored. From the complete cluster list, preliminary inclusion and exclusion criteria were applied (eg, age) to generate a list of all potential trial participants (eligible contacts and contacts of contacts) to be approached for consent. Eligible contacts and contacts of contacts cluster-randomised to immediate vaccination had only one opportunity to give their informed consent; ie, during the first contact (day 0). Eligible contacts and contacts of contacts assigned to delayed clusters had two opportunities to consent: day 0 and day 21 when vaccination was offered to the cluster.

Active surveillance for, and laboratory confirmation of, cases of Ebola virus disease were independently undertaken by the national surveillance system, and cases of Ebola virus disease were confirmed by designated surveillance laboratories.The national Ebola surveillance team and the trial team were independent; the trial team did not communicate any specific information to the surveillance teams and laboratories about which cases of Ebola virus disease were used to form a new cluster or which people would be included in a cluster.

We used block randomisation randomly varying block sizes, stratified by location (urban vs rural) and size of rings (≤20 vs >20 individuals). The randomisation list was stored in a data management system not accessible to anyone involved in the recruitment of trial participants. Allocation of a cluster was done once the enumeration of the cluster (ie, the list of contacts and contacts of contacts) was done. Allocation of the cluster was informed to the participants at the end of the informed consent process. In the pilot phase and after July 27, 2015, clusters were not randomised and all eligible participants received the vaccine immediately after informed consent.

Contacts and contacts of contacts of individuals with Ebola virus disease were enumerated into clusters (and the information stored on a list) and these clusters were cluster-randomised (1:1) to either immediate vaccination or delayed vaccination (21 days later) of all eligible individuals.The teams who defined the clusters were different from the team who took informed consent or did the vaccinations. Randomisation took place only after the list enumerating all the contacts and contacts of contacts of a cluster was closed. An independent statistician not otherwise involved in the trial generated the allocation sequence, and Ebola response teams and laboratory workers were unaware of the allocation of clusters.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

Additionally, in view of emerging data for vaccine safety among children aged 6–17 years,the protocol was amended on Aug 15, 2015, to also include children in this age group. Consequently, we obtained written informed consent from the parents or guardians of children aged 6–17 years with written assent from children aged 12–17 years.

The trial personnel were predominantly composed of nationals from Guinea and other African countries. An internal quality assurance and quality control system was put in place, with 100% monitoring of study documents. An independent data and safety monitoring board (DSMB) reviewed the study protocol and the analysis plan before the analysis and assessed adverse events and efficacy results. The pilot phase of the trial began on March 23, 2015, and random assignment of clusters started on April 1, 2015. On July 31, 2015, random assignment into immediate and delayed vaccination was discontinued on the recommendation of the DSMB, whose decision took into consideration the interim analysis showing 100% vaccine efficacy(although they noted that the prespecified α spending criterion of 0·0027 was not achieved) and the low probability of being able to recruit substantial numbers of additional rings (given the declining number of cases of Ebola virus disease in the country). Thereafter, all identified rings received immediate vaccination. Ring enrolment was concluded on Jan 20, 2016.

A team obtained written informed consent from all eligible contacts and contacts of contacts using a printed information sheet. If the person in question was illiterate, these documents were read to him or her in their local language and a fingerprint from the participant and the signature of an independent literate witness documented consent. Eligible contacts and contacts of contacts were informed of the outcome of the randomisation at the end of the informed consent process.

We randomly assigned clusters into immediate vaccination or vaccination delayed by 21 days. Exclusion criteria were: history of Ebola virus disease (self-declared or laboratory confirmed), being aged less than 18 years, pregnancy (verbally declared) or breastfeeding (women were invited, but not forced, to take a pregnancy test), history of administration of other experimental treatments during the past 28 days, history of anaphylaxis to a vaccine or vaccine component, or serious disease requiring confining to bed or admission to hospital by the time of vaccination. Within each cluster, all people who were eligible and consented were offered vaccination.

Briefly, we enumerated clusters as a list of all contacts and contacts of contacts of the index case including residents temporarily absent at the time of enumeration. We defined contacts as individuals who lived in the same household, visited or were visited by the index case after the onset of symptoms, provided him or her with unprotected care, or prepared the body for the traditional funeral ceremony. These contacts included high-risk contacts who were in close physical contact with the patient's body or body fluids, linen, or clothes.Contacts of contacts were the neighbours of the index case to the nearest appropriate geographical boundary plus the household members of any high-risk contacts living away from the index cases' residence. A new cluster was defined if at least 60% of the contacts and contacts of contacts were not enumerated in a previous cluster.

Ebola virus spread across many geographical areas of Guinea, mainly through familial and social networks and funeral exposures.After confirmation of a case of Ebola virus disease (index case), we enumerated and randomised clusters (called rings) of epidemiologically linked people.The ring vaccination design ensured that the study was undertaken in pockets of high incidence of Ebola virus disease despite the declining epidemic and an overall low attack rate (ie, the total number of cases of Ebola virus disease in the three worst affected countries divided by the estimated total population of these countries; estimated here as about 0·13%). Details of the study protocol, study team composition, study procedures, and statistical analysis plan have been previously reported.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

Ebola ça Suffit ring vaccination trial consortium The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola.

Transmission of Ebola viruses: what we know and what we do not know.

The Guinean national medicines regulatory agency (Direction Nationale de la Pharmacie et du Laboratoire) and the national ethics committee (Comité National d'Ethique pour la Recherche en Santé), the WHO Ethical Research Committee, and Norwegian Regional Committees for Medical and Health Research Ethics approved the study protocol. In Aug, 2015, after approval by Sierra Leonean National Regulatory Authority and the Ethics Review Committee, the trial was extended to Sierra Leone (Tomkolili and Bombali).

The Guinea ring vaccination trial was a cluster-randomised controlled trial designed to assess the effect of one dose of the candidate vaccine in protecting against laboratory confirmed Ebola virus disease. We did this trial in the community in Conakry and eight surrounding prefectures in the Basse-Guinée region of Guinea ( appendix ).

Results

Figure 1 Trial profile Show full caption The vaccine effects analyses set included all eligible contacts and contacts of contacts and the safety analysis set included all participants who had received the vaccine. Participants were analysed in the group corresponding to the allocated arm. *Including two non-randomised rings from Sierra Leone with 325 contacts and 255 contacts of contacts. †Including three pilot rings. During the trial period between March 23, 2015, and Jan 20, 2016, there were 476 cases of Ebola virus disease in Guinea, all in the study area. 117 were index cases for clusters, 27 were index cases and also endpoints. In total, 105 were endpoints (75 among the eligible contacts and contacts of contacts and 30 among non-eligible contacts and contacts of contacts). We did not define a cluster around 281 (59%) of the cases of Ebola virus disease occurring during this period. These 281 cases of Ebola virus disease mostly arose during March and April, 2015, during the pilot phase and when most study teams were still being trained and the study did not have full capacity ( figure 1 appendix ).

In all, we obtained aliquots from 79% (93/117) Ebola virus disease index cases; 88% (30/34) of confirmed Ebola virus disease outcome cases with onset 10 or more days after randomisation and 80% (57/71) of all confirmed Ebola virus disease outcome cases. 5837 individuals in total received the vaccine (5643 adults and 194 children); all were followed up for 84 days.

Table 1 Baseline characteristics of clusters and index cases Randomised Not randomised Assigned to immediate vaccination (51 clusters) Assigned to delayed vaccination (47 clusters) Assigned to immediate vaccination (19 clusters) All clusters (117 clusters) Index cases used to define clusters Age (years) 35 (18–43) 35 (27–50) 23 (13–42) 35 (20–47) Women 27/51 (53%) 31/47 (66%) 12/19 (63%) 70/117 (60%) Dead at time of randomisation 30/51 (59%) 32/47 (68%) 9/19 (47%) 71/117 (61%) Time from onset of symptoms to admission to hospitalisation or isolation (days) 3·9 (2·9) 3·8 (2·6) 3·2 (2·4) 3·7 (2·7) Time from onset of symptoms for index cases to randomisation of cluster (days) 9·7 (5·3) 11 (4·1) .. 10·3 (4·8) Time from onset of symptoms for index cases to inclusion of cluster (days) 9·8 (5·1) 10·9 (4·1) 7·3 (3·7) 9·9 (4·6) Characteristics of clusters Located in rural areas 39/51 (76%) 36/47 (77%) 9/19 (47%) 84/117 (72%) Total number of people in cluster 80 (64–101) 81 (69–118) 105 (49–185) 83 (66–115) Data are median (IQR), n/N (%), or mean (SD). ..=not applicable. The measured characteristics of index cases of Ebola virus disease and clusters were broadly comparable at baseline for immediate, delayed, and non-randomised clusters, including time from onset to randomisation and the proportion of index cases who were dead at the time of randomisation ( table 1 ). Mean time from symptom onset in index cases to ring inclusion was 9·8 days in immediate rings, 10·9 days in delayed rings, and 7·3 days in non-randomised rings. Randomised clusters had a median 80 people (IQR 64–101) for immediate and a median 81 people (69–118) for delayed clusters. Non-randomised clusters were slightly larger with a median 105 people (49–185), partly due to public knowledge of the interim results as well as to the eligibility extension to children aged 6 years and older.

Table 2 Baseline characteristics of eligible contacts and contacts of contacts Randomly assigned Not randomly assigned * * Six non-randomised rings included children aged 6 years and older (n=273). Totality of evidence Assigned to immediate vaccination (51 clusters, n=3232) Assigned to delayed vaccination (47 clusters, n=3096) Assigned to immediate vaccination (19 clusters, n=2006) All clusters (117 clusters, n=8334) Consent No consent Consent visit day 0 † † Informed consent was obtained either during the first visit (day 0) or the second visit (day 21) of the trial team. Consent visit day 21 † † Informed consent was obtained either during the first visit (day 0) or the second visit (day 21) of the trial team. No consent Consent No consent Immediately vaccinated Delayed or never vaccinated Individuals' characteristics Number of individuals 2151 1081 1435 1104 557 1678 328 3796 4538 Age (years) 40 (29–55) 30 (25–45) 39 (27–53) 37 (27–50) 32 (23–45) 30 (22–44) 25 (18–35) 35 (25–50) 35 (25–50) Women 640/2151 (30%) 608/1081 (56%) 428/1434 (30%) 404/1104 (37%) 319/557 (57.3%) 593/1678 (35%) 179/328 (54.6%) 1223/3796 (32%) 1948/4537 (43%) Contacts with index cases No detailed contact information (no consent) 0/2151 1081/1081 (100%) 0/1435 0/1104 557/557 (100%) 0/1678 328/328 (100%) 0/3796 1966/4538 (43%) Contact of contact ‡ ‡ Proportion calculated among individuals with available contact information. Two individuals were pregnant and one was severely ill. 1727/2151 (80%) .. 1160/1435 (81%) 971/1104 (88%) .. 1418/1678 (85%) .. 3116/3796 (82%) 2160/2572 (84%) Contact ‡ ‡ Proportion calculated among individuals with available contact information. Two individuals were pregnant and one was severely ill. 424/2151 (20%) .. 275/1435 (19%) 133/1104 (12%) .. 260/1678 (15%) .. 680/3796 (18%) 412/2572 (16%) High-risk contact ‡ ‡ Proportion calculated among individuals with available contact information. Two individuals were pregnant and one was severely ill. 330/2151 (15%) .. 171/1435 (12%) 58/1104 (5%) .. 246/1678 (15%) .. 574/3796 (15%) 231/2572 (9%) Data are median (IQR) or n/N (%). ..=data not available. At baseline, the characteristics of contacts and contacts of contacts in all comparator groups for immediate, delayed and non-randomised clusters were largely comparable ( table 2 appendix ). A higher fraction of high-risk contacts was included in the immediate clusters. More than 80% of contacts and contacts of contacts were defined as contacts of contacts. Compliance with follow-up visits on all types of clusters and for all scheduled visits was more than 80% with no differences between groups ( appendix ).

Table 1, Table 2; Table 1, Table 2; In the randomised part of the trial, there were 4539 contacts and contacts of contacts in 51 clusters in the immediate vaccination arm (of whom 3232 were eligible, 2151 consented, and 2119 were immediately vaccinated) and 4557 contacts and contacts of contacts in 47 clusters in the delayed vaccination arm (of whom 3096 were eligible, 2539 consented and 2041 were vaccinated 21 days after randomisation; figure 1 ). In immediate clusters, 34% (1113/3232) of eligible individuals were not vaccinated mainly because informed consent was not obtained (n=728) or it was withdrawn (n=32), or because individuals were absent at the time of the team's visit (n=353; figure 1 appendix ). In delayed clusters, 34% (1055/3096) of eligible individuals were not vaccinated mainly because informed consent was not obtained or it was withdrawn (n=788) or because individuals were absent at the time of the team's visit (n=252) or developed Ebola virus disease during the 0–20 days period (n=12; figure 1 appendix ). Additionally, two individuals were pregnant, and one was severely ill, so these were not vaccinated. Among those who consented in the delayed clusters, 57% (1435/2539) gave their consent during the first visit with the study team (day 0) and 43% (1104/2539) gave consent on the vaccination visit (day 21); all were included in the cluster enumeration list.

20 Ebola ça Suffit ring vaccination trial consortium

The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola. Table 3 Effect of vaccine on cases of Ebola virus disease in different study populations All clusters * * Randomly assigned and non-randomly assigned individuals who were allocated to immediate vaccination were combined. Randomised clusters † † Non-randomised immediate clusters are excluded from this analysis. 1 2 3 4 5 6 7 8 All vaccinated in immediate (group A) vs all contacts and contacts of contacts in delayed plus all never-vaccinated in immediate or non-randomised (group B) All vaccinated in immediate (group A) vs all eligible in delayed plus all eligible never-vaccinated in immediate (group B) All contacts and contacts of contacts in immediate (group A) vs delayed (group B) All vaccinated in immediate (group A) vs all eligible never vaccinated in immediate (group B) All vaccinated in immediate (group A) vs all eligible and consented on day 0 visit in delayed (group B) All vaccinated in immediate (group A) vs all eligible in delayed (group B) All eligible in immediate (group A) vs all eligible delayed (group B) All contacts and contacts of contacts in immediate (group A) vs all contacts and contacts of contacts in delayed (group B) Group A Number of individuals (clusters) 3775 (70) 3775 (70) 7241 (70) 3775 (70) 2108 (51) 2108 (51) 3212 (51) 4513 (51) Cases of Ebola virus disease (clusters affected) 0 (0) 0 (0) 12 (7) 0 (0) 0 (0) 0 (0) 7 (4) 10 (5) Attack rate 0% 0% 0·17% 0% 0% 0% 0·22% 0·22% Group B Number of individuals (clusters) 7995 (116) 4507 (104) 4529 (47) 1432 (57) 1429 (46) 3075 (47) 3075 (47) 4529 (47) Cases of Ebola virus disease (clusters affected) 34 (15) 23 (11) 22 (8) 7 (4) 10 (4) 16 (7) 16 (7) 22 (8) Attack rate 0·43% 0·51% 0·49% 0·49% 0·7% 0·52% 0·52% 0·49% Vaccine effect Vaccine efficacy/effectiveness ‡ ‡ From fitting a β-binomial distribution to the cluster-level numerators and denominators and using an inverted likelihood ratio test to identify the lower bound for vaccine efficacy (columns 1, 2, 5, and 6); from a Cox proportional hazards model (column 3, 7, and 8); from signed test (two-sided): probability of observing endpoints in control groups among treatment–control mismatched pairs and under the null hypothesis that the vaccine has no efficacy (column 4). 100% (77·0 to 100·0) 100% (79·3 to 100·0) 70·1% (−4·9 to 91·5) 100% (−51·5 to 100·0) 100% (63·5 to 100·0) 100% (68·9 to 100·0) 64·6% (−46·5 to 91·4) 64·6% (−44·2 to 91·3) p value § § From Fisher's exact test (two-sided), which is approximate for columns 1 and 2. From signed test (two-sided): probability of observing endpoints in control groups among treatment–control mismatched pairs and under the null hypothesis that the vaccine has no efficacy (column 4). 0·0012 0·0033 0·2759 0·125 0·0471 0·0045 0·344 0·3761 Random assignment had little effect on the onset of Ebola virus disease during days 0–9. 20 cases of Ebola virus disease occurred among 3232 eligible contacts and contacts of contacts (nine clusters affected) in 51 immediate clusters versus 21 cases among 3096 eligible contacts and contacts of contacts (14 clusters affected) in 47 delayed clusters ( table 3 appendix ). However, vaccine allocation reduced Ebola virus disease onset to 0 cases from 10 days post-randomisation in immediately vaccinated contacts and contacts of contacts versus ten cases of Ebola virus disease (four clusters affected) among the eligible contacts and contacts of contacts in delayed clusters who gave consent on day 0. Vaccine efficacy was still 100% ( table 3 ). The calculated intraclass coefficient (ICC) was high at 0·14, largely due to clustering of six confirmed endpoint cases of Ebola virus disease in one of the clusters. This would make the Fisher's test even more conservative. This ICC value contrasts with the ICC value of 0·05that we used to estimate the trial sample size and power calculation ( appendix ).

One additional case of Ebola virus disease was identified in the delayed clusters among eligible contacts and contacts of contacts who consented on day 21 for a total of 11 cases of Ebola virus disease among eligible and consenting contacts and contacts of contacts in delayed clusters. The remaining ten cases in the delayed clusters were among the eligible contacts and contacts of contacts who consented on day 0. Among these 11 cases of Ebola virus disease, including four vaccinees (onset 0, 2, 6, and 6 days after vaccination), seven (64%) were among unvaccinated contacts (one high-risk contact) and the four others were contacts of contacts ( appendix ).

The overall ring vaccination effectiveness in protecting all contacts and contacts of contacts in the randomised clusters (including unvaccinated cluster members) was 64·6% ( table 3 ), with 65·6% of the eligible contacts and contacts of contacts receiving the vaccine at the cluster level.

No cases of Ebola virus disease occurred 10 days or more after randomisation among randomly assigned contacts and contacts of contacts vaccinated in immediate clusters versus 16 cases (7 clusters affected) among all eligible individuals in delayed clusters ( table 3 ). Vaccine efficacy was 100% (95% CI 68·9–100·0, p=0·0045), and the calculated ICC was 0·035. Additionally, we enumerated 2745 contacts and contacts of contacts (three in the pilot phase) in 19 non-randomised clusters, 2006 of whom were eligible and 1677 were immediately vaccinated, including 194 children aged 6–17 years ( figure 1 ).

Table 4; Table 4 Distribution of confirmed cases of Ebola virus disease among enumerated contacts and contacts of contacts in all clusters Eligible adults assigned to immediate vaccination All eligible adults assigned to delayed vaccination Eligible adults not assigned Non-eligible * * 19 Osterholm MT

Moore KA

Kelley NS

et al. Transmission of Ebola viruses: what we know and what we do not know. 20 Ebola ça Suffit ring vaccination trial consortium

The ring vaccination trial: a novel cluster randomised controlled trial design to evaluate vaccine efficacy and effectiveness during outbreaks, with special reference to Ebola. Aged <18 years, pregnant, or lactating (full list of exclusion criteria in participants (not vaccinated) Immediately Vaccinated Never vaccinated Immediately Vaccinated Never vaccinated All assigned to immediate vaccination All assigned to delayed vaccination All not assigned Contacts and contacts of contacts (clusters) 2119 (51) 1113 (48) 3096 (47) 1677 (19) 329 (10) 1307 (50) 1461 (47) 739 (19) Attack rates Overall 11/2119 (0·5%) 16/1113 (1·4%) 37/3096 (1·2%) 10/1677 (0·6%) 1/329 (0·3%) 9/1307 (0·7%) 13/1461 (0·9%) 8/739 (1·1%) Onset <10 days since being randomly assigned 11/2111 (0·5%) 9/1113 (0·8%) 21/3096 (0·7%) 10/1677 (0·6%) 1/329 (0·3%) 6/1307 (0·5%) 7/1461 (0·5%) 6/739 (0·8%) Onset ≥10 days since being randomly assigned 0/2108 7/1104 (0·6%) 16/3075 (0·5%) 0/1667 0/328 3/1301 (0·2%) 6/1454 (0·4%) 2/733 (0·3%) Clusters affected by cases with onset ≥10 days after being randomly assigned 0 cases 51/51 (100%) 44/48 (91·7%) 40/47 (85·1%) 19/19 (100%) 10/10 (100%) 48/50 (96%) 44/47 (93·6%) 17/19 (89·5%) 1 case .. 2/48 (4·2%) 3/47 (6·4%) .. .. 1/50 (2%) 2/47 (4·3%) 2/19 (10·5%) 2 cases .. 1/48 (2·1%) 2/47 (4·3%) .. .. 1/50 (2%) .. .. 3 cases .. 1/48 (2·1%) 1/47 (2·1%) .. .. .. .. .. 4 cases .. .. .. .. .. .. 1/47 (2·1%) .. 6 cases .. .. 1/47 (2·1%) .. .. .. .. .. The evidence from all 117 clusters (randomised and non-randomised) showed that no cases of Ebola virus disease occurred 10 days or more after randomisation among the 3775 immediately vaccinated contacts and contacts of contacts versus 23 cases (11 clusters affected) among the 4507 eligible contacts and contacts of contacts in delayed plus all eligible contacts and contacts of contacts never vaccinated in immediate clusters ( Table 3 appendix ). Of these 23 cases of Ebola virus disease, four were vaccinated but had onset of Ebola virus disease at days 0, 2, 6, and 6 after vaccination and the remaining 19 cases were among non-vaccinated contacts and contacts of contacts. Thus, immediate vaccination resulted in complete protection against subsequent onset of Ebola virus disease 10 days later or more. The estimated vaccine efficacy here was 100% (95% CI 79·3–100·0, p=0·0033; table 4 ). 52% of contacts and contacts of contacts assigned to immediate vaccination and in non-randomised clusters received the vaccine immediately; vaccination protected both vaccinated and unvaccinated people in those clusters.

Figure 2 Kaplan-Meier plots for all confirmed cases of Ebola virus disease among all contacts and contacts of contacts in immediate, delayed, and non-randomised clusters Show full caption Arrows show time of vaccination (at day 0 or day 21). The shaded area denotes the a priori defined lag time of 0–9 days. *Individuals aged 6–18 years were eligible for immediate vaccination in non-pilot, non-randomised rings. Description of Ebola virus disease cases 10 days or more after randomisation: A (allocated to delayed vaccination): 22 cases; six were children (aged <18 years); one was eligible and did not consent; four were absent; 11 were eligible and consented, including seven eligible and consented with illness onset on days 10–20 after randomisation plus four eligible, consented, and delayed vaccinated with onset on days 21–30 after randomisation (0, 2, 6, and 6 days after their delayed vaccination). B: ten cases, all unvaccinated; two were children (aged <18 years); four were eligible and did not consent; three were absent; one was not eligible (ie, pregnant, breastfeeding, or severely ill). C: two cases, both were children (aged <6 years and hence unvaccinated). Cases occurred in the first 10 days after randomisation for all comparison groups, at similar times; there were no cases of Ebola virus disease among vaccinees from 10 days after randomisation or vaccination in any of the groups, with all cases arising in clusters more than 10 days post-vaccination occurring in unvaccinated individuals ( figure 2 ). Additionally, the rVSV-ZEBOV vaccine seemed to have contributed to interrupt Ebola transmission in the clusters because no cases of Ebola virus disease among vaccinees or unvaccinated individuals were observed in immediate vaccinated clusters after 21 days after vaccination ( figure 2 ). Details about the distribution of cases of Ebola virus disease among the various groups are in table 4 and the appendix

Because no cases of Ebola virus disease occurred at 10 days or later in the vaccinated group, the vaccine effect was high for all the comparisons of vaccine effect on deaths due to Ebola virus disease ( appendix ), with 100% effect (95% CI 62·6–100, p=0·0102) when comparing all vaccinated in immediate clusters versus all eligible in delayed clusters. We were not able to do the planned secondary analyses on vaccine effect against probable and suspected cases because of near-universality of laboratory testing of such cases in Guinea during the study period, leaving only 26/502 (5%) of cases without a definitive diagnosis. Five cases of Ebola virus disease initially considered as index cases for clusters were negative by confirmatory retesting and the corresponding clusters were therefore excluded from the analysis. No endpoint cases tested negative on confirmatory retesting.

Figure 3 Kaplan-Meier plots for confirmed cases of Ebola virus disease in different study populations Show full caption Arrows show time of vaccination (at day 0 or day 21); the plus signs denote cases among non-eligible children and the stars denote cases among vaccinated individuals; the shaded area denotes the a priori defined lag time of 0–9 days. In total, we identified 105 cases of Ebola virus disease among all contacts and contacts of contacts (eligible or not for vaccination) in the 117 clusters defined (98 randomised clusters and 19 non-randomised clusters). The overall attack rate was 0·9% (95% CI 0·7–1·1) considering the 105 cases occurring among 11 841 individuals enumerated in 117 rings. None of the cases occurred in vaccinated individuals 10 days or more after being vaccinated ( figure 3 appendix ).

Moreover, when comparing all contacts and contacts of contacts in clusters immediately vaccinated versus all contacts and contacts of contacts in delayed clusters plus all contacts and contacts of contacts never vaccinated in immediate or non-randomised clusters, vaccine protection was 100% ( table 3 ) further indicating that the vaccine is highly protective ( table 4 appendix ). This represents the totality of evidence for high vaccine efficacy when comparing all immediately vaccinated people to all delayed or unvaccinated people. The overall ring vaccination effectiveness in protecting all contacts and contacts of contacts (including vaccinated and unvaccinated cluster members) was 70·1% ( table 3 ) with 52·1% (3796/7284) of the contacts and contacts of contacts vaccinated.

Cases occurred in the first 10 days at a similar time in immediate, delayed, and non-randomised clusters and all comparison groups. There were no cases of Ebola virus disease among vaccinees from 10 days post-vaccination in any of the groups ( figure 3 appendix ). Moreover, rVSV-ZEBOV vaccine contributed to interrupt Ebola transmission with no cases of Ebola virus disease after 32 days after randomisation in randomly assigned and non-randomly assigned clusters in vaccinated and non-vaccinated individuals ( Figure 2 Figure 3 ).

Table 5 Frequency of solicited adverse events by time since vaccination in children and adults. 0–30 min 31 min to 3 days 4–14 days Children aged between 6–<18 years (n=194) Arthralgia 0 3 (3·5%) 1 (9.1%) Diarrhoea 0 0 1 (9·1%) Fatigue 0 10 (11·6%) 1 (9·1%) Fever 0 1 (1·2%) 1 (9·1%) Headache 0 47 (54·7%) 4 (36·4%) Induration 0 0 0 Injection pain 0 9 (10·5%) 0 Muscle pain 0 4 (4·7%) 1 (9·1%) Myalgia 0 4 (4·7%) 1 (9·1%) Vomiting 0 1 (1·2%) 0 Other adverse events 0 7 (8·1%) 1 (9·1%) Total 0 86 (100·0%) 11 (100·0%) Adults aged 18 years and older (n=5643) Arthralgia 3 (2%) 851 (13·5%) 79 (12·3%) Diarrhoea 0 53 (0·8%) 15 (2·3%) Fatigue 5 (3·3%) 1233 (19·5%) 112 (17·4%) Fever 2 (1·3%) 8 (0·1%) 2 (0·3%) Headache 41 (27·3%) 1563 (24·7%) 177 (27·5%) Induration 0 1 (<1%) 0 Injection pain 70 (46·7%) 362 (5·7%) 8 (1·2%) Muscle pain 7 (4·7%) 875 (13·8%) 55 (8·5%) Myalgia 6 (4·0%) 816 (12·9%) 47 (7·3%) Vomiting 0 21 (0·3%) 4 (0·6%) Other adverse events 16 (10·7%) 537 (8·5%) 145 (22·5%) Total 150 (100·0%) 6320 (100·0%) 644 (100·0%) Data are n (%); individuals might have had more than one adverse event. 3149 (53·9%) of 5837 individuals reported at least one adverse event in the 14 days after vaccination ( appendix ); across all adverse events, solicited and unsolicited, 87·5% (6311/7211) were mild, 11·0% (793/7211) moderate, and 1·2% (83/7211) severe ( appendix ). Across all age groups, headache (1832 [25·4%]), fatigue (1361 [18·9%]), and muscle pain (942 [13·1%) were the most commonly reported adverse events in this period across all age groups. Data from children indicated that in the 3 days after vaccination, by percentage of individuals with the events, the commonly reported adverse events were headache (51/97 [52·6%]), fatigue (11/97 [11·3%]), and injection pain (9/97 [9·3%]). Adults most commonly reported headache (1781/7114 [25·0%]), fatigue (1350/7114 [19·0%]), and muscle pain (937/7114 [13·2%]) in the same period. Arthralgia was the fourth most reported adverse event ( table 5 ; reported by 17·9% of vaccinated participants), and was reported in 4/180 (2·2%) of vaccinated children with a mean duration of 4·5 days (IQR 3–5) and in 915/4960 (18·5%) of vaccinated adults with a mean duration of 2 days (2–4). Cases resolved spontaneously without sequelae.