Your search keyword '"Hinsley WR"' showing total 8 results

1. Assessing transmissibility of SARS-CoV-2 lineage B.1.1.7 in England

Author

Volz, E, Mishra, S, Chand, M, Barrett, JC, Johnson, R, Geidelberg, L, Hinsley, WR, Laydon, DJ, Dabrera, G, O’Toole, Á, Amato, R, Ragonnet-Cronin, M, Harrison, I, Jackson, B, Ariani, CV, Boyd, O, Loman, NJ, McCrone, JT, Gonçalves, S, Jorgensen, D, Myers, R, Hill, V, Jackson, DK, Gaythorpe, K, Groves, N, Sillitoe, J, Kwiatkowski, DP, Koshy, C, Ash, A, Wise, E, Moore, N, Mori, M, Cortes, N, Lynch, J, Kidd, S, Fairley, DJ, Curran, T, McKenna, JP, Adams, H, Fraser, C, Golubchik, T, Bonsall, D, Hassan-Ibrahim, MO, Malone, CS, Cogger, BJ, Wantoch, M, Reynolds, N, Warne, B, Maksimovic, J, Spellman, K, McCluggage, K, John, M, Beer, R, Afifi, S, Morgan, S, Marchbank, A, Price, A, Kitchen, C, Gulliver, H, Merrick, I, Southgate, J, Guest, M, Munn, R, Workman, T, Connor, TR, Fuller, W, Bresner, C, Snell, LB, Patel, A, Charalampous, T, Nebbia, G, Batra, R, Edgeworth, J, Robson, SC, Beckett, AH, Aanensen, DM, Underwood, AP, Yeats, CA, Abudahab, K, Taylor, BEW, Menegazzo, M, Clark, G, Smith, W, Khakh, M, Fleming, VM, Lister, MM, Howson-Wells, HC, Berry, L, Boswell, T, Joseph, A, Willingham, I, Jones, C, Holmes, C, Bird, P, Helmer, T, Fallon, K, Tang, J, Raviprakash, V, Campbell, S, and Sheriff, N

Abstract

The SARS-CoV-2 lineage B.1.1.7, designated variant of concern (VOC) 202012/01 by Public Health England1, was first identified in the UK in late summer to early autumn 20202. Whole-genome SARS-CoV-2 sequence data collected from community-based diagnostic testing for COVID-19 show an extremely rapid expansion of the B.1.1.7 lineage during autumn 2020, suggesting that it has a selective advantage. Here we show that changes in VOC frequency inferred from genetic data correspond closely to changes inferred by S gene target failures (SGTF) in community-based diagnostic PCR testing. Analysis of trends in SGTF and non-SGTF case numbers in local areas across England shows that B.1.1.7 has higher transmissibility than non-VOC lineages, even if it has a different latent period or generation time. The SGTF data indicate a transient shift in the age composition of reported cases, with cases of B.1.1.7 including a larger share of under 20-year-olds than non-VOC cases. We estimated time-varying reproduction numbers for B.1.1.7 and co-circulating lineages using SGTF and genomic data. The best-supported models did not indicate a substantial difference in VOC transmissibility among different age groups, but all analyses agreed that B.1.1.7 has a substantial transmission advantage over other lineages, with a 50% to 100% higher reproduction number.

Published

2021

2. Transmission of SARS-CoV-2 Lineage B.1.1.7 in England: Insights from linking epidemiological and genetic data

Author

Volz, E, Mishra, S, Chand, M, Barrett, JC, Johnson, R, Geidelberg, L, Hinsley, WR, Laydon, DJ, Dabrera, G, O’Toole, Á, Amato, R, Ragonnet-Cronin, M, Harrison, I, Jackson, B, Ariani, CV, Boyd, O, Loman, N, McCrone, JT, Gon\c calves, S, Jorgensen, D, Myers, R, Hill, V, Jackson, DK, Gaythorpe, K, Groves, N, Sillitoe, J, Kwiatkowski, DP, Flaxman, S, Ratman, O, Bhatt, S, Hopkins, S, Gandy, A, Rambaut, A, and Ferguson, NM

Abstract

The SARS-CoV-2 lineage B.1.1.7, now designated Variant of Concern 202012/01 (VOC) by Public Health England, originated in the UK in late Summer to early Autumn 2020. We examine epidemiological evidence for this VOC having a transmission advantage from several perspectives. First, whole genome sequence data collected from community-based diagnostic testing provides an indication of changing prevalence of different genetic variants through time. Phylodynamic modelling additionally indicates that genetic diversity of this lineage has changed in a manner consistent with exponential growth. Second, we find that changes in VOC frequency inferred from genetic data correspond closely to changes inferred by S-gene target failures (SGTF) in community-based diagnostic PCR testing. Third, we examine growth trends in SGTF and non-SGTF case numbers at local area level across England, and show that the VOC has higher transmissibility than non-VOC lineages, even if the VOC has a different latent period or generation time. Available SGTF data indicate a shift in the age composition of reported cases, with a larger share of under 20 year olds among reported VOC than non-VOC cases. Fourth, we assess the association of VOC frequency with independent estimates of the overall SARS-CoV-2 reproduction number through time. Finally, we fit a semi-mechanistic model directly to local VOC and non-VOC case incidence to estimate the reproduction numbers over time for each. There is a consensus among all analyses that the VOC has a substantial transmission advantage, with the estimated difference in reproduction numbers between VOC and non-VOC ranging between 0.4 and 0.7, and the ratio of reproduction numbers varying between 1.4 and 1.8. We note that these estimates of transmission advantage apply to a period where high levels of social distancing were in place in England; extrapolation to other transmission contexts therefore requires caution.Competing Interest StatementThe authors have declared no competing interest.Funding StatementCOG-UK is supported by funding from the Medical Research Council (MRC) part of UK Research & Innovation (UKRI), the National Institute of Health Research (NIHR) and Genome Research Limited, operating as the Wellcome Sanger Institute. The Imperial College COVID-19 Research Fund, UKRI (MR/V038109/1), The Academy of Medical Sciences (SBF004/1080), Bill & Melinda Gates Foundation (OPP1197730, OPP1175094), the European Commission (CoroNAb 101003653), the NIHR BRC Imperial College NHS Trust Infection and COVID themes (RDA02), Amazon AWS and Microsoft AI for Health, the EPSRC, The Medical Research Council (MR/R015600/1), the NIHR Health Protection Research Unit for Modelling and Health Economics, NIHR VEEPD project funding. Wellcome core funding to the Wellcome Sanger Institute (206194).Author DeclarationsI confirm all relevant ethical guidelines have been followed, and any necessary IRB and/or ethics committee approvals have been obtained.YesThe details of the IRB/oversight body that provided approval or exemption for the research described are given below:NAAll necessary patient/participant consent has been obtained and the appropriate institutional forms have been archived.YesI understand that all clinical trials and any other prospective interventional studies must be registered with an ICMJE-approved registry, such as ClinicalTrials.gov. I confirm that any such study reported in the manuscript has been registered and the trial registration ID is provided (note: if posting a prospective study registered retrospectively, please provide a statement in the trial ID field explaining why the study was not registered in advance).Yes I have followed all appropriate research reporting guidelines and uploaded the relevant EQUATOR Network research reporting checklist(s) and other pertinent material as supplementary files, if applicable.YesAll aggregated data to reproduce analysis will be provided in the url below.https://github.com/mrc-ide/covid19-variant-N501Y

Published

2021

3. Impact of proactive and reactive vaccination strategies for health-care workers against MERS-CoV: a mathematical modelling study.

Author

Laydon DJ, Cauchemez S, Hinsley WR, Bhatt S, and Ferguson NM

Subjects

Humans, Vaccination, Health Personnel, Disease Outbreaks prevention & control, Middle East Respiratory Syndrome Coronavirus, Epidemics prevention & control

Abstract

Background: Several vaccine candidates are in development against MERS-CoV, which remains a major public health concern. In anticipation of available MERS-CoV vaccines, we examine strategies for their optimal deployment among health-care workers., Methods: Using data from the 2013-14 Saudi Arabia epidemic, we use a counterfactual analysis on inferred transmission trees (who-infected-whom analysis) to assess the potential impact of vaccination campaigns targeting health-care workers, as quantified by the proportion of cases or deaths averted. We investigate the conditions under which proactive campaigns (ie vaccinating in anticipation of the next outbreak) would outperform reactive campaigns (ie vaccinating in response to an unfolding outbreak), considering vaccine efficacy, duration of vaccine protection, effectiveness of animal reservoir control measures, wait (time between vaccination and next outbreak, for proactive campaigns), reaction time (for reactive campaigns), and spatial level (hospital, regional, or national, for reactive campaigns). We also examine the relative efficiency (cases averted per thousand doses) of different strategies., Findings: The spatial scale of reactive campaigns is crucial. Proactive campaigns outperform campaigns that vaccinate health-care workers in response to outbreaks at their hospital, unless vaccine efficacy has waned significantly. However, reactive campaigns at the regional or national levels consistently outperform proactive campaigns, regardless of vaccine efficacy. When considering the number of cases averted per vaccine dose administered, the rank order is reversed: hospital-level reactive campaigns are most efficient, followed by regional-level reactive campaigns, with national-level and proactive campaigns being least efficient. If the number of cases required to trigger reactive vaccination increases, the performance of hospital-level campaigns is greatly reduced; the impact of regional-level campaigns is variable, but that of national-level campaigns is preserved unless triggers have high thresholds., Interpretation: Substantial reduction of MERS-CoV morbidity and mortality is possible when vaccinating only health-care workers, underlining the need for countries at risk of outbreaks to stockpile vaccines when available., Funding: UK Medical Research Council, UK National Institute for Health Research, UK Research and Innovation, UK Academy of Medical Sciences, The Novo Nordisk Foundation, The Schmidt Foundation, and Investissement d'Avenir France., Competing Interests: Declaration of interests DJL, WRH, SB, and NMF report grants from the UK Medical Research Council (MRC) and the Department for International Development. DJL, SB, and NMF report grants from the UK National Institute for Health and Care Research (NIHR). SC reports grant funding from the Investissement d'Avenir programme, Laboratoire d'Excellence Integrative Biology of Emerging Infectious Diseases programme, and INCEPTION project, outside of the submitted work. SB reports grant funding from Novo Nordisk Foundation, the Danish National Research Foundation, and The Eric & Wendy Schmidt Fund for Strategic Innovation, outside of the submitted work. NMF reports grants from UK Research and Innovation; Community Jameel; Gavi, the Vaccine Alliance; Janssen Pharmaceuticals; and the Bill & Melinda Gates Foundation, outside of the submitted work. Additionally, NMF reports consulting fees for the World Bank Group (ceased in 2019); payment for sitting on a grant panel and an advisory board for the Wellcome Trust; travel expenses for WHO meetings; and sitting on an advisory board for Takeda in relation to their dengue vaccine, for which no honoraria, gifts, or expenses of any kind were received. NMF is a senior editor for the journal eLife. All other authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY 4.0 license. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

4. Lives saved with vaccination for 10 pathogens across 112 countries in a pre-COVID-19 world.

Author

Toor J, Echeverria-Londono S, Li X, Abbas K, Carter ED, Clapham HE, Clark A, de Villiers MJ, Eilertson K, Ferrari M, Gamkrelidze I, Hallett TB, Hinsley WR, Hogan D, Huber JH, Jackson ML, Jean K, Jit M, Karachaliou A, Klepac P, Kraay A, Lessler J, Li X, Lopman BA, Mengistu T, Metcalf CJE, Moore SM, Nayagam S, Papadopoulos T, Perkins TA, Portnoy A, Razavi H, Razavi-Shearer D, Resch S, Sanderson C, Sweet S, Tam Y, Tanvir H, Tran Minh Q, Trotter CL, Truelove SA, Vynnycky E, Walker N, Winter A, Woodruff K, Ferguson NM, and Gaythorpe KA

Subjects

Bacterial Infections epidemiology, Humans, Bacterial Infections prevention & control, Bacterial Vaccines therapeutic use, COVID-19, Global Health, Models, Biological, SARS-CoV-2

Abstract

Background: Vaccination is one of the most effective public health interventions. We investigate the impact of vaccination activities for Haemophilus influenzae type b, hepatitis B, human papillomavirus, Japanese encephalitis, measles, Neisseria meningitidis serogroup A, rotavirus, rubella, Streptococcus pneumoniae , and yellow fever over the years 2000-2030 across 112 countries., Methods: Twenty-one mathematical models estimated disease burden using standardised demographic and immunisation data. Impact was attributed to the year of vaccination through vaccine-activity-stratified impact ratios., Results: We estimate 97 (95%CrI[80, 120]) million deaths would be averted due to vaccination activities over 2000-2030, with 50 (95%CrI[41, 62]) million deaths averted by activities between 2000 and 2019. For children under-5 born between 2000 and 2030, we estimate 52 (95%CrI[41, 69]) million more deaths would occur over their lifetimes without vaccination against these diseases., Conclusions: This study represents the largest assessment of vaccine impact before COVID-19-related disruptions and provides motivation for sustaining and improving global vaccination coverage in the future., Funding: VIMC is jointly funded by Gavi, the Vaccine Alliance, and the Bill and Melinda Gates Foundation (BMGF) (BMGF grant number: OPP1157270 / INV-009125). Funding from Gavi is channelled via VIMC to the Consortium's modelling groups (VIMC-funded institutions represented in this paper: Imperial College London, London School of Hygiene and Tropical Medicine, Oxford University Clinical Research Unit, Public Health England, Johns Hopkins University, The Pennsylvania State University, Center for Disease Analysis Foundation, Kaiser Permanente Washington, University of Cambridge, University of Notre Dame, Harvard University, Conservatoire National des Arts et Métiers, Emory University, National University of Singapore). Funding from BMGF was used for salaries of the Consortium secretariat (authors represented here: TBH, MJ, XL, SE-L, JT, KW, NMF, KAMG); and channelled via VIMC for travel and subsistence costs of all Consortium members (all authors). We also acknowledge funding from the UK Medical Research Council and Department for International Development, which supported aspects of VIMC's work (MRC grant number: MR/R015600/1).JHH acknowledges funding from National Science Foundation Graduate Research Fellowship; Richard and Peggy Notebaert Premier Fellowship from the University of Notre Dame. BAL acknowledges funding from NIH/NIGMS (grant number R01 GM124280) and NIH/NIAID (grant number R01 AI112970). The Lives Saved Tool (LiST) receives funding support from the Bill and Melinda Gates Foundation.This paper was compiled by all coauthors, including two coauthors from Gavi. Other funders had no role in study design, data collection, data analysis, data interpretation, or writing of the report. All authors had full access to all the data in the study and had final responsibility for the decision to submit for publication., Competing Interests: JT, SE, XL, KA, EC, HC, AC, Md, KE, MF, IG, TH, WH, DH, JH, KJ, AK, PK, AK, JL, XL, TM, CM, SM, SN, TP, AP, DR, SR, CS, SS, YT, HT, QT, ST, EV, NW, AW, KW, NF, KG No competing interests declared, MJ MLJ has received research funding from Sanofi Pasteur unrelated to the present work, MJ Reviewing editor, eLife, BL BAL reports grants and personal fees from Takeda Pharmaceuticals, personal fees from World Health Organization, outside the submitted work, TP TAP receives support from Emergent Biosolutions for work unrelated to his contribution to this study, HR HR is an employee of Center for Disease Analysis Foundation which has received grants from Gilead Sciences, AbbVie, Zeshan Foundation and EndHep2030 fund for projects unrelated to this work; HBV epidemiology data was funded by a grant from John Martin Foundation (Grant number 24), CT CLT received a consulting payment from GSK in 2018 (outside the submitted work), (© 2021, Toor et al.)

Published

2021

5. Efficacy profile of the CYD-TDV dengue vaccine revealed by Bayesian survival analysis of individual-level phase III data.

Author

Laydon DJ, Dorigatti I, Hinsley WR, Nedjati-Gilani G, Coudeville L, and Ferguson NM

Subjects

Adolescent, Bayes Theorem, Child, Child, Preschool, Dengue pathology, Dengue Vaccines adverse effects, Humans, Serogroup, Survival Analysis, Dengue prevention & control, Dengue Vaccines immunology, Dengue Virus classification, Models, Biological

Abstract

Background: Sanofi-Pasteur's CYD-TDV is the only licensed dengue vaccine. Two phase three trials showed higher efficacy in seropositive than seronegative recipients. Hospital follow-up revealed increased hospitalisation in 2-5- year-old vaccinees, where serostatus and age effects were unresolved., Methods: We fit a survival model to individual-level data from both trials, including year 1 of hospital follow-up. We determine efficacy by age, serostatus, serotype and severity, and examine efficacy duration and vaccine action mechanism., Results: Our modelling indicates that vaccine-induced immunity is long-lived in seropositive recipients, and therefore that vaccinating seropositives gives higher protection than two natural infections. Long-term increased hospitalisation risk outweighs short-lived immunity in seronegatives. Independently of serostatus, transient immunity increases with age, and is highest against serotype 4. Benefit is higher in seropositives, and risk enhancement is greater in seronegatives, against hospitalised disease than against febrile disease., Conclusions: Our results support vaccinating seropositives only. Rapid diagnostic tests would enable viable 'screen-then-vaccinate' programs. Since CYD-TDV acts as a silent infection, long-term safety of other vaccine candidates must be closely monitored., Funding: Bill & Melinda Gates Foundation, National Institute for Health Research, UK Medical Research Council, Wellcome Trust, Royal Society., Clinical Trial Number: NCT01373281 and NCT01374516., Competing Interests: DL, ID, WH, GN, NF No competing interests declared, LC Laurent Coudeville is employed by Sanofi-Pasteur, (© 2021, Laydon et al.)

Published

2021

6. Assessing transmissibility of SARS-CoV-2 lineage B.1.1.7 in England.

Author

Volz E, Mishra S, Chand M, Barrett JC, Johnson R, Geidelberg L, Hinsley WR, Laydon DJ, Dabrera G, O'Toole Á, Amato R, Ragonnet-Cronin M, Harrison I, Jackson B, Ariani CV, Boyd O, Loman NJ, McCrone JT, Gonçalves S, Jorgensen D, Myers R, Hill V, Jackson DK, Gaythorpe K, Groves N, Sillitoe J, Kwiatkowski DP, Flaxman S, Ratmann O, Bhatt S, Hopkins S, Gandy A, Rambaut A, and Ferguson NM

Subjects

Adolescent, Adult, Age Distribution, Aged, Aged, 80 and over, Basic Reproduction Number, COVID-19 diagnosis, COVID-19 epidemiology, Child, Child, Preschool, England epidemiology, Evolution, Molecular, Genome, Viral genetics, Humans, Infant, Infant, Newborn, Middle Aged, SARS-CoV-2 genetics, SARS-CoV-2 isolation & purification, Spike Glycoprotein, Coronavirus analysis, Spike Glycoprotein, Coronavirus genetics, Time Factors, Young Adult, COVID-19 transmission, COVID-19 virology, Phylogeny, SARS-CoV-2 classification, SARS-CoV-2 pathogenicity

Abstract

The SARS-CoV-2 lineage B.1.1.7, designated variant of concern (VOC) 202012/01 by Public Health England 1 , was first identified in the UK in late summer to early autumn 2020 2 . Whole-genome SARS-CoV-2 sequence data collected from community-based diagnostic testing for COVID-19 show an extremely rapid expansion of the B.1.1.7 lineage during autumn 2020, suggesting that it has a selective advantage. Here we show that changes in VOC frequency inferred from genetic data correspond closely to changes inferred by S gene target failures (SGTF) in community-based diagnostic PCR testing. Analysis of trends in SGTF and non-SGTF case numbers in local areas across England shows that B.1.1.7 has higher transmissibility than non-VOC lineages, even if it has a different latent period or generation time. The SGTF data indicate a transient shift in the age composition of reported cases, with cases of B.1.1.7 including a larger share of under 20-year-olds than non-VOC cases. We estimated time-varying reproduction numbers for B.1.1.7 and co-circulating lineages using SGTF and genomic data. The best-supported models did not indicate a substantial difference in VOC transmissibility among different age groups, but all analyses agreed that B.1.1.7 has a substantial transmission advantage over other lineages, with a 50% to 100% higher reproduction number.

Published

2021

7. Modelling the impact of the tier system on SARS-CoV-2 transmission in the UK between the first and second national lockdowns.

Author

Laydon DJ, Mishra S, Hinsley WR, Samartsidis P, Flaxman S, Gandy A, Ferguson NM, and Bhatt S

Subjects

Bayes Theorem, Communicable Disease Control, Humans, Pandemics, United Kingdom epidemiology, COVID-19, SARS-CoV-2

Abstract

Objective: To measure the effects of the tier system on the COVID-19 pandemic in the UK between the first and second national lockdowns, before the emergence of the B.1.1.7 variant of concern., Design: This is a modelling study combining estimates of real-time reproduction number R t (derived from UK case, death and serological survey data) with publicly available data on regional non-pharmaceutical interventions. We fit a Bayesian hierarchical model with latent factors using these quantities to account for broader national trends in addition to subnational effects from tiers., Setting: The UK at lower tier local authority (LTLA) level. 310 LTLAs were included in the analysis., Primary and Secondary Outcome Measures: Reduction in real-time reproduction number R t ., Results: Nationally, transmission increased between July and late September, regional differences notwithstanding. Immediately prior to the introduction of the tier system, R t averaged 1.3 (0.9-1.6) across LTLAs, but declined to an average of 1.1 (0.86-1.42) 2 weeks later. Decline in transmission was not solely attributable to tiers. Tier 1 had negligible effects. Tiers 2 and 3, respectively, reduced transmission by 6% (5%-7%) and 23% (21%-25%). 288 LTLAs (93%) would have begun to suppress their epidemics if every LTLA had gone into tier 3 by the second national lockdown, whereas only 90 (29%) did so in reality., Conclusions: The relatively small effect sizes found in this analysis demonstrate that interventions at least as stringent as tier 3 are required to suppress transmission, especially considering more transmissible variants, at least until effective vaccination is widespread or much greater population immunity has amassed., Competing Interests: Competing interests: None declared., (© Author(s) (or their employer(s)) 2021. Re-use permitted under CC BY. Published by BMJ.)

Published

2021

8. Pandemic potential of a strain of influenza A (H1N1): early findings.

Author

Fraser C, Donnelly CA, Cauchemez S, Hanage WP, Van Kerkhove MD, Hollingsworth TD, Griffin J, Baggaley RF, Jenkins HE, Lyons EJ, Jombart T, Hinsley WR, Grassly NC, Balloux F, Ghani AC, Ferguson NM, Rambaut A, Pybus OG, Lopez-Gatell H, Alpuche-Aranda CM, Chapela IB, Zavala EP, Guevara DM, Checchi F, Garcia E, Hugonnet S, and Roth C

Subjects

Global Health, Humans, Influenza, Human mortality, Influenza, Human transmission, Influenza, Human virology, Mexico epidemiology, Molecular Sequence Data, Travel, Disease Outbreaks, Influenza A Virus, H1N1 Subtype, Influenza, Human epidemiology

Abstract

A novel influenza A (H1N1) virus has spread rapidly across the globe. Judging its pandemic potential is difficult with limited data, but nevertheless essential to inform appropriate health responses. By analyzing the outbreak in Mexico, early data on international spread, and viral genetic diversity, we make an early assessment of transmissibility and severity. Our estimates suggest that 23,000 (range 6000 to 32,000) individuals had been infected in Mexico by late April, giving an estimated case fatality ratio (CFR) of 0.4% (range: 0.3 to 1.8%) based on confirmed and suspected deaths reported to that time. In a community outbreak in the small community of La Gloria, Veracruz, no deaths were attributed to infection, giving an upper 95% bound on CFR of 0.6%. Thus, although substantial uncertainty remains, clinical severity appears less than that seen in the 1918 influenza pandemic but comparable with that seen in the 1957 pandemic. Clinical attack rates in children in La Gloria were twice that in adults (<15 years of age: 61%; >/=15 years: 29%). Three different epidemiological analyses gave basic reproduction number (R0) estimates in the range of 1.4 to 1.6, whereas a genetic analysis gave a central estimate of 1.2. This range of values is consistent with 14 to 73 generations of human-to-human transmission having occurred in Mexico to late April. Transmissibility is therefore substantially higher than that of seasonal flu, and comparable with lower estimates of R0 obtained from previous influenza pandemics.

Published

2009