Your search keyword '"Hinsley W"' showing total 76 results

1. Quantifying the effect of delaying the second COVID-19 vaccine dose in England: a mathematical modelling study

Author

Imai, N, Rawson, T, Knock, ES, Sonabend, R, Elmaci, Y, Perez-Guzman, PN, Whittles, LK, Kanapram, DT, Gaythorpe, KAM, Hinsley, W, Djaafara, BA, Wang, H, Fraser, K, FitzJohn, RG, Hogan, AB ; https://orcid.org/0000-0002-6271-9921, Doohan, P, Ghani, AC, Ferguson, NM, Baguelin, M, Cori, A, Imai, N, Rawson, T, Knock, ES, Sonabend, R, Elmaci, Y, Perez-Guzman, PN, Whittles, LK, Kanapram, DT, Gaythorpe, KAM, Hinsley, W, Djaafara, BA, Wang, H, Fraser, K, FitzJohn, RG, Hogan, AB ; https://orcid.org/0000-0002-6271-9921, Doohan, P, Ghani, AC, Ferguson, NM, Baguelin, M, and Cori, A

Abstract

Background: The UK was the first country to start national COVID-19 vaccination programmes, initially administering doses 3 weeks apart. However, early evidence of high vaccine effectiveness after the first dose and the emergence of the SARS-CoV-2 alpha variant prompted the UK to extend the interval between doses to 12 weeks. In this study, we aimed to quantify the effect of delaying the second vaccine dose in England. Methods: We used a previously described model of SARS-CoV-2 transmission, calibrated to COVID-19 surveillance data from England, including hospital admissions, hospital occupancy, seroprevalence data, and population-level PCR testing data, using a Bayesian evidence-synthesis framework. We modelled and compared the epidemic trajectory in the counterfactual scenario in which vaccine doses were administered 3 weeks apart against the real reported vaccine roll-out schedule of 12 weeks. We estimated and compared the resulting numbers of daily infections, hospital admissions, and deaths. In sensitivity analyses, we investigated scenarios spanning a range of vaccine effectiveness and waning assumptions. Findings: In the period from Dec 8, 2020, to Sept 13, 2021, the number of individuals who received a first vaccine dose was higher under the 12-week strategy than the 3-week strategy. For this period, we estimated that delaying the interval between the first and second COVID-19 vaccine doses from 3 to 12 weeks averted a median (calculated as the median of the posterior sample) of 58 000 COVID-19 hospital admissions (291 000 cumulative hospitalisations [95% credible interval 275 000–319 000] under the 3-week strategy vs 233 000 [229 000–238 000] under the 12-week strategy) and 10 100 deaths (64 800 deaths [60 200–68 900] vs 54 700 [52 800–55 600]). Similarly, we estimated that the 3-week strategy would have resulted in more infections compared with the 12-week strategy. Across all sensitivity analyses the 3-week strategy resulted in a greater number of hospita

Published

2023

2. Report 51: Evidence for age dependence in the severity of the Omicron SARS-CoV variant of concern relative to the Delta variant

Author

Ferguson, N, Ghani, A, Hinsley, W, and Volz, E

Subjects

Coronavirus, COVID19, Omicron, SARS-CoV-2, COVID-19

Published

2022

3. Report 49: Growth, population distribution and immune escape of Omicron in England

Author

Ferguson, N, Ghani, A, Cori, A, Hogan, A, Hinsley, W, Volz, E, and Medical Research Council (MRC)

Subjects

Coronavirus, COVID-19

Abstract

To estimate the growth of the Omicron variant of concern (1) and its immune escape (2–9) characteristics, we analysed data from all PCR-confirmed SARS-CoV-2 cases in England excluding those with a history of recent international travel. We undertook separate analyses according to two case definitions. For the first definition, we included all cases with a definitive negative S-gene Target Failure (SGTF) result and specimen dates between 29/11/2021 and 11/12/2021 inclusive. For the second definition, we included cases with a positive genotype result and specimen date between 23/11/2021 and 11/12/2021 inclusive. We chose a later start date for the SGTF definition to ensure greater specificity of SGTF for Omicron. We used logistic and Poisson regression to identify factors associated with testing positive for Omicron compared to non-Omicron (mostly Delta) cases. We explored the following predictors: day, region, symptomatic status, sex, ethnicity, age band and vaccination status. Our results suggest rapid growth of the frequency of the Omicron variant relative to Delta, with the exponential growth rate of its frequency estimated to be 0.34/day (95% CI: 0.33-0.35) [2.0 day doubling time] over the study period from both SGTF and genotype data. The distribution of Omicron by age, region and ethnicity currently differs markedly from Delta, with 18–29-year-olds, residents in the London region, and those of African ethnicity having significantly higher rates of infection with Omicron relative to Delta. Hospitalisation and asymptomatic infection indicators were not significantly associated with Omicron infection, suggesting at most limited changes in severity compared with Delta. To estimate the impact of Omicron on vaccine effectiveness (VE) for symptomatic infection we used conditional Poisson regression to estimate the hazard ratio of being an Omicron case (using SGTF definition) compared with Delta, restricting our analysis to symptomatic cases and matching by day, region, 10-year age band, sex and ethnicity. We found a significant increased risk of an Omicron case compared to Delta for those with vaccine status AZ 2+weeks post-dose 2 (PD2) , Pfizer 2+w PD2, AZ 2+w post-dose 3 (PD3) and PF 2+w PD3 vaccine states with hazard ratios of 1.86 (95%CI: 1.67-2.08), 2.68 (95%CI: 2.54-2.83), 4.32 (95%CI: 3.84-4.85) and 4.07 (95%CI: 3.66-4.51), respectively, where PD3 states are categorised by the dose 1/2 vaccine used. Depending on the Delta VE estimates used (10), these estimates translate into Omicron VE estimates of between 0% and 20% PD2 and between 55% and 80% PD3 against Omicron, consistent with other estimates (11). Similar estimates were obtained using genotype data, albeit with greater uncertainty. To assess the impact of Omicron on reinfection rates we relied on genotype data, since SGTF is associated with a higher observed rate of reinfection, likely due to reinfections typically having higher Ct values than primary infections and therefore being subject to a higher rate of random PCR target failure. Controlling for vaccine status, age, sex, ethnicity, asymptomatic status, region and specimen date and using conditional Poisson regression to predict reinfection status, Omicron was associated with a 5.41 (95% CI: 4.87-6.00) fold higher risk of reinfection compared with Delta. This suggests relatively low remaining levels of immunity from prior infection.

Published

2021

4. Report 50: Hospitalisation risk for Omicron cases in England

Author

Ferguson, N, Ghani, A, Hinsley, W, Volz, E, On behalf of the Imperial College COVID-19 Response Team, and Medical Research Council (MRC)

Subjects

Coronavirus, COVID-19

Abstract

To assess differences in the risk of hospitalisation between the Omicron variant of concern (1) and the Delta variant, we analysed data from all PCR-confirmed SARS-CoV-2 cases in England with last test specimen dates between 1st and 14th December inclusive. Variant was defined using a combination of S-gene Target Failure (SGTF) and genetic data. Case data were linked by National Health service (NHS) number to the National Immunisation Management System (NIMS) database, the NHS Emergency Care (ECDS) and Secondary Use Services (SUS) hospital episode datasets. Hospital attendance was defined as any record of attendance at a hospital by a case in the 14 days following their last positive PCR test, up to and including the day of attendance. A secondary analysis examined the subset of attendances with a length of stay of one or more days. We used stratified conditional Poisson regression to predict hospitalisation status, with demographic strata defined by age, sex, ethnicity, region, specimen date, index of multiple deprivation and in some analyses, vaccination status. Predictor variables were variant (Omicron or Delta), reinfection status and vaccination status. Overall, we find evidence of a reduction in the risk of hospitalisation for Omicron relative to Delta infections, averaging over all cases in the study period. The extent of reduction is sensitive to the inclusion criteria used for cases and hospitalisation, being in the range 20-25% when using any attendance at hospital as the endpoint, and 40-45% when using hospitalisation lasting 1 day or longer or hospitalisations with the ECDS discharge field recorded as “admitted” as the endpoint (Table 1). These reductions must be balanced against the larger risk of infection with Omicron, due to the reduction in protection provided by both vaccination and natural infection. A previous infection reduces the risk of any hospitalisation by approximately 50% (Table 2) and the risk of a hospital stay of 1+ days by 61% (95%CI:55-65%) (before adjustments for under ascertainment of reinfections). High historical infection attack rates and observed reinfection rates with Omicron mean it is necessary to correct hazard ratio estimates to accurately quantify intrinsic differences in severity between Omicron and Delta and to assess the protection afforded by past infection. The resulting adjustments are moderate (typically less than an increase of 0.2 in the hazard ratio for Omicron vs Delta and a reduction of approximately 0.1 in the hazard ratio for reinfections vs primary infections) but significant for evaluating severity overall. Using a hospital stay of 1+ days as the endpoint, the adjusted estimate of the relative risk of reinfections versus primary cases is 0.31, a 69% reduction in hospitalisation risk (Table 2). Stratifying hospitalisation risk by vaccination state reveals a more complex overall picture, albeit consistent with the unstratified analysis. This showed an apparent difference between those who received AstraZenca (AZ) vaccine versus Pfizer or Moderna (PF/MD) for their primary series (doses 1 and 2). Hazard ratios for hospital attendance with Omicron for PF/MD are similar to those seen for Delta in those vaccination categories, while Omicron hazard ratios are generally lower than for Delta for the AZ vaccination categories. Given the limited samples sizes to date, we caution about over-interpreting these trends, but they are compatible with previous findings that while protection afforded against mild infection from AZ was substantially reduced with the emergency of Delta, protection against more severe outcomes was sustained (2,3). We emphasise that these are estimates which condition upon infection; net vaccine effectiveness against hospital attendance may not vary between the vaccines, given that PF/MD maintain higher effectiveness against symptomatic infection with Omicron than AZ (4). Our estimates will assist in refining mathematical models of potential healthcare demand associated with the unfolding European Omicron wave. The hazard ratios provided in Table 3 can be translated into estimates of vaccine effectiveness (VE) against hospitalisation, given estimates of VE against infection (4). In broad terms, our estimates suggest that individuals who have received at least 2 vaccine doses remain substantially protected against hospitalisation, even if protection against infection has been largely lost against the Omicron variant (4,5).

Published

2021

5. Exploring relationships between drought and epidemic cholera in Africa using generalised linear models

Author

Charnley, GEC, Kelman, I, Green, N, Gaythorpe, KAM, Murray, KA, Hinsley, W, and Natural Environment Research Council

Subjects

1108 Medical Microbiology, 1103 Clinical Sciences, Microbiology, 0605 Microbiology

Abstract

Background Temperature and precipitation are known to affect Vibrio cholerae outbreaks. Despite this, the impact of drought on outbreaks has been largely understudied. Africa is both drought and cholera prone and more research is needed in Africa to understand cholera dynamics in relation to drought. Methods Here, we analyse a range of environmental and socioeconomic covariates and fit generalised linear models to publicly available national data, to test for associations with several indices of drought and make cholera outbreak projections to 2070 under three scenarios of global change, reflecting varying trajectories of CO2 emissions, socio-economic development, and population growth. Results The best-fit model implies that drought is a significant risk factor for African cholera outbreaks, alongside positive effects of population, temperature and poverty and a negative effect of freshwater withdrawal. The projections show that following stringent emissions pathways and expanding sustainable development may reduce cholera outbreak occurrence in Africa, although these changes were spatially heterogeneous. Conclusions Despite an effect of drought in explaining recent cholera outbreaks, future projections highlighted the potential for sustainable development gains to offset drought-related impacts on cholera risk. Future work should build on this research investigating the impacts of drought on cholera on a finer spatial scale and potential non-linear relationships, especially in high-burden countries which saw little cholera change in the scenario analysis. Competing Interest Statement The authors have declared no competing interest. Funding Statement This work was supported by the Natural Environmental Research Council [NE/S007415] as part of the Grantham Institute for Climate Change and the Environments (Imperial College London) Science and Solutions for a Changing Planet Doctoral Training Partnership. We also acknowledge joint Centre funding from the UK Medical Research Council and Department for International Development [MR/R0156600/1].

Published

2021

6. Report 41: The 2020 SARS-CoV-2 epidemic in England: key epidemiological drivers and impact of interventions

Author

Knock, E, Whittles, L, Lees, J, Perez Guzman, P, Verity, R, Fitzjohn, R, Gaythorpe, K, Imai, N, Hinsley, W, Okell, L, Rosello, A, Kantas, N, Walters, C, Bhatia, S, Watson, O, Whittaker, C, Cattarino, L, Boonyasiri, A, Djaafara, A, Fraser, K, Fu, H, Wang, H, Xi, X, Donnelly, C, Jauneikaite, E, Laydon, D, White, P, Ghani, A, Ferguson, N, Cori, A, Baguelin, M, and Medical Research Council (MRC)

Subjects

Coronavirus, England, COVID19, COVID-19, United Kingdom, Real Time Modelling

Abstract

England has been severely affected by COVID-19. We fitted a model of SARS-CoV-2 transmission in care homes and the community to regional 2020 surveillance data. Only national lockdown brought the reproduction number below 1 consistently; introduced one week earlier in the first wave it could have reduced mortality by 23,300 deaths on average. The mean infection fatality ratio was initially ~1.3% across all regions except London and halved following clinical care improvements. The infection fatality ratio was two-fold lower throughout in London, even when adjusting for demographics. The infection fatality ratio in care homes was 2.5-times that in the elderly in the community. Population-level infection-induced immunity in England is still far from herd immunity, with regional mean cumulative attack rates ranging between 4.4% and 15.8%.

Published

2020

7. Report 33: Modelling the allocation and impact of a COVID-19 vaccine

Author

Hogan, A, Winskill, P, Watson, O, Walker, P, Whittaker, C, Baguelin, M, Haw, D, Lochen, A, Gaythorpe, K, Ainslie, K, Bhatt, S, Boonyasiri, A, Boyd, O, Brazeau, N, Cattarino, L, Charles, G, Cooper, L, Coupland, H, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Donnelly, C, Dorigatti, I, Eales, O, Van Elsland, S, Ferreira Do Nascimento, F, Fitzjohn, R, Flaxman, S, Green, W, Hallett, T, Hamlet, A, Hinsley, W, Imai, N, Jauneikaite, E, Jeffrey, B, Knock, E, Laydon, D, Lees, J, Mellan, T, Mishra, S, Nedjati Gilani, G, Nouvellet, P, Ower, A, Parag, K, Ragonnet-Cronin, M, Siveroni, I, Skarp, J, Thompson, H, Unwin, H, Verity, R, Vollmer, M, Volz, E, Walters, C, Wang, H, Wang, Y, Whittles, L, Xi, X, Muhib, F, Smith, P, Hauck, K, Ferguson, N, Ghani, A, Medical Research Council (MRC), and Abdul Latif Jameel Foundation

Subjects

Coronavirus, COVID19, COVID-19, Vaccine

Abstract

Several SARS-CoV-2 vaccine candidates are now in late-stage trials, with efficacy and safety results expected by the end of 2020. Even under optimistic scenarios for manufacture and delivery, the doses available in 2021 are likely to be limited. Here we identify optimal vaccine allocation strategies within and between countries to maximise health (avert deaths) under constraints on dose supply. We extended an existing mathematical model of SARS-CoV-2 transmission across different country settings to model the public health impact of potential vaccines, using a range of target product profiles developed by the World Health Organization. We show that as supply increases, vaccines that reduce or block infection – and thus transmission – in addition to preventing disease have a greater impact than those that prevent disease alone, due to the indirect protection provided to high-risk groups. We further demonstrate that the health impact of vaccination will depend on the cumulative infection incidence in the population when vaccination begins, the duration of any naturally acquired immunity, the likely trajectory of the epidemic in 2021 and the level of healthcare available to effectively treat those with disease. Within a country, we find that for a limited supply (doses for

Published

2020

8. Report 31: Estimating the burden of COVID-19 in Damascus, Syria: an analysis of novel data sources to infer mortality under-ascertainment

Author

Van Elsland, S, Watson, O, Alhaffar, M, Mehchy, Z, Whittaker, C, Akil, Z, Ainslie, K, Baguelin, M, Bhatt, S, Boonyasiri, A, Boyd, O, Brazeau, N, Cattarino, L, Charles, G, Ciavarella, C, Cooper, L, Coupland, H, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Djaafara, A, Donnelly, C, Dorigatti, I, Eales, O, Nascimento, F, Fitzjohn, R, Flaxman, S, Forna, A, Fu, H, Gaythorpe, K, Green, W, Hamlet, A, Hauck, K, Haw, D, Hayes, S, Hinsley, W, Imai, N, Jeffrey, B, Johnson, R, Jorgensen, D, Knock, E, Laydon, D, Lees, J, Mellan, T, Mishra, S, Nedjati Gilani, G, Nouvellet, P, Okell, L, Olivera Mesa, D, Pons Salort, M, Ragonnet-Cronin, M, Siveroni, I, Stopard, I, Thompson, H, Unwin, H, Verity, R, Vollmer, M, Volz, E, Walters, C, Wang, H, Wang, Y, Whittles, L, Winskill, P, Xi, X, Ferguson, N, Beals, E, Walker, P, Anonymous Authors, Medical Research Council (MRC), and Abdul Latif Jameel Foundation

Subjects

Coronavirus, Syria, COVID19, COVID-19

Abstract

The COVID-19 pandemic has resulted in substantial mortality worldwide. However, to date, countries in the Middle East and Africa have reported substantially lower mortality rates than in Europe and the Americas. One hypothesis is that these countries have been ‘spared’, but another is that deaths have been under-ascertained (deaths that have been unreported due to any number of reasons, for instance due to limited testing capacity). However, the scale of under-ascertainment is difficult to assess with currently available data. In this analysis, we estimate the potential under-ascertainment of COVID-19 mortality in Damascus, Syria, where all-cause mortality data has been reported between 25th July and 1st August. We fit a mathematical model of COVID-19 transmission to reported COVID-19 deaths in Damascus since the beginning of the pandemic and compare the model-predicted deaths to reported excess deaths. Exploring a range of different assumptions about under-ascertainment, we estimate that only 1.25% of deaths (sensitivity range 1% - 3%) due to COVID-19 are reported in Damascus. Accounting for under-ascertainment also corroborates local reports of exceeded hospital bed capacity. To validate the epidemic dynamics inferred, we leverage community-uploaded obituary certificates as an alternative data source, which confirms extensive mortality under-ascertainment in Damascus between July and August. This level of under-ascertainment suggests that Damascus is at a much later stage in its epidemic than suggested by surveillance reports, which have repo. We estimate that 4,340 (95% CI: 3,250 - 5,540) deaths due to COVID-19 in Damascus may have been missed as of 2nd September 2020. Given that Damascus is likely to have the most robust surveillance in Syria, these findings suggest that other regions of the country could have experienced similar or worse mortality rates due to COVID-19.

Published

2020

9. Report 30: The COVID-19 epidemic trends and control measures in mainland China

Author

Fu, H, Xi, X, Wang, H, Boonyasiri, A, Wang, Y, Hinsley, W, Fraser, K, McCabe, R, Olivera Mesa, D, Skarp, J, Ledda, A, Dewe, T, Dighe, A, Winskill, P, Van Elsland, S, Ainslie, K, Baguelin, M, Bhatt, S, Boyd, O, Brazeau, N, Cattarino, L, Charles, G, Coupland, H, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Donnelly, C, Dorigatti, I, Green, W, Hamlet, A, Hauck, K, Haw, D, Jeffrey, B, Laydon, D, Lees, J, Mellan, T, Mishra, S, Nedjati Gilani, G, Nouvellet, P, Okell, L, Parag, K, Ragonnet-Cronin, M, Riley, S, Schmit, N, Thompson, H, Unwin, H, Verity, R, Vollmer, M, Volz, E, Walker, P, Walters, C, Watson, O, Whittaker, C, Whittles, L, Imai, N, Bhatia, S, Ferguson, N, and Medical Research Council (MRC)

Subjects

Coronavirus, China, COVID19, COVID-19

Published

2020

10. Potential impact of the COVID-19 pandemic on HIV, TB and malaria in low- and middle-income countries: a modelling study

Author

Hogan, A, Jewell, B, Sherrard-Smith, E, Watson, O, Whittaker, C, Hamlet, A, Smith, J, Winskill, P, Verity, R, Baguelin, M, Lees, J, Whittles, L, Ainslie, K, Bhatt, S, Boonyasiri, A, Brazeau, N, Cattarino, L, Cooper, L, Coupland, H, Cuomo-Dannenburg, G, Dighe, A, Djaafara, A, Donnelly, C, Eaton, J, Van Elsland, S, Fitzjohn, R, Fu, H, Gaythorpe, K, Green, W, Haw, D, Hayes, S, Hinsley, W, Imai, N, Laydon, D, Mangal, T, Mellan, T, Mishra, S, Parag, K, Thompson, H, Unwin, H, Vollmer, M, Walters, C, Wang, H, Ferguson, N, Okell, L, Churcher, T, Arinaminpathy, N, Ghani, A, Walker, P, Hallett, T, Medical Research Council (MRC), Bill & Melinda Gates Foundation, Wellcome Trust, Imperial College Healthcare NHS Trust- BRC Funding, The Academy of Medical Sciences, National Institute for Health Research, Imperial College LOndon, Medical Research Council, and The Royal Society

Subjects

Pneumonia, Viral, Humans, Tuberculosis, HIV Infections, Models, Theoretical, Coronavirus Infections, Developing Countries, Pandemics, Health Services Accessibility, Malaria, 0605 Microbiology, 1117 Public Health and Health Services

Abstract

Background: COVID-19 has the potential to cause substantial disruptions to health services, including by cases overburdening the health system or response measures limiting usual programmatic activities. We aimed to quantify the extent to which disruptions in services for human immunodeficiency virus (HIV), tuberculosis (TB) and malaria in low- and middle-income countries with high burdens of those disease could lead to additional loss of life. Methods: We constructed plausible scenarios for the disruptions that could be incurred during the COVID-19 pandemic and used established transmission models for each disease to estimate the additional impact on health that could be caused in selected settings. Findings: In high burden settings, HIV-, TB- and malaria-related deaths over five years may increase by up to 10%, 20% and 36%, respectively, compared to if there were no COVID-19 pandemic. We estimate the greatest impact on HIV to be from interruption to antiretroviral therapy, which may occur during a period of high health system demand. For TB, we estimate the greatest impact is from reductions in timely diagnosis and treatment of new cases, which may result from any prolonged period of COVID-19 suppression interventions. We estimate that the greatest impact on malaria burden could come from interruption of planned net campaigns. These disruptions could lead to loss of life-years over five years that is of the same order of magnitude as the direct impact from COVID-19 in places with a high burden of malaria and large HIV/TB epidemics. Interpretation: Maintaining the most critical prevention activities and healthcare services for HIV, TB and malaria could significantly reduce the overall impact of the COVID-19 pandemic. Funding: Bill & Melinda Gates Foundation, The Wellcome Trust, DFID, MRC

Published

2020

11. Estimating the number of undetected COVID-19 cases among travellers from mainland China

Author

Bhatia, S, Imai, N, Cuomo-Dannenburg, G, Baguelin, M, Boonyasiri, A, Cori, A, Cucunuba Perez, Z, Dorigatti, I, Fitzjohn, R, Fu, H, Gaythorpe, K, Ghani, A, Hamlet, A, Hinsley, W, Laydon, D, Nedjati Gilani, G, Okell, L, Riley, S, Thompson, H, Van Elsland, S, Volz, E, Wang, H, Wang, Y, Whittaker, C, Xi, X, Donnelly, CA, Ferguson, NM, and Medical Research Council (MRC)

Abstract

Background: Since the start of the COVID-19 epidemic in late 2019, there have been more than 152 affected regions and countries with over 110,000 confirmed cases outside mainland China. Methods: We analysed COVID-19 cases among travellers from mainland China to different regions and countries, comparing the region- and country-specific rates of detected and confirmed cases per flight volume to estimate the relative sensitivity of surveillance in different regions and countries. Results: Although travel restrictions from Wuhan City and other cities across China may have reduced the absolute number of travellers to and from China, we estimated that more than two thirds (70%, 95% CI: 54% - 80%, compared to Singapore; 75%, 95% CI: 66% - 82%, compared to multiple countries) of cases exported from mainland China have remained undetected. Conclusions: These undetected cases potentially resulted in multiple chains of human-to-human transmission outside mainland China.

Published

2020

12. Report 26: Reduction in mobility and COVID-19 transmission

Author

Nouvellet, P, Bhatia, S, Cori, A, Ainslie, K, Baguelin, M, Bhatt, S, Boonyasiri, A, Brazeau, N, Cattarino, L, Cooper, L, Coupland, H, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Dighe, A, Djaafara, A, Dorigatti, I, Eales, O, Van Elsland, S, Nscimento, F, Fitzjohn, R, Gaythorpe, K, Geidelberg, L, Grassly, N, Green, W, Hamlet, A, Hauck, K, Hinsley, W, Imai, N, Jeffrey, B, Knock, E, Laydon, D, Lees, J, Mangal, T, Mellan, T, Nedjati Gilani, G, Parag, K, Pons Salort, M, Ragonnet-Cronin, M, Riley, S, Unwin, H, Verity, R, Vollmer, M, Volz, E, Walker, P, Walters, C, Wang, H, Watson, O, Whittaker, C, Whittles, L, Xi, X, Ferguson, N, Donnelly, C, and Medical Research Council (MRC)

Subjects

Mobility, COVID19, Transmissibility, COVID-19

Abstract

In response to the COVID-19 pandemic, countries have sought to control transmission of SARS-CoV-2 by restricting population movement through social distancing interventions, reducing the number of contacts. Mobility data represent an important proxy measure of social distancing. Here, we develop a framework to infer the relationship between mobility and the key measure of population-level disease transmission, the reproduction number (R). The framework is applied to 53 countries with sustained SARS-CoV-2 transmission based on two distinct country-specific automated measures of human mobility, Apple and Google mobility data. For both datasets, the relationship between mobility and transmission was consistent within and across countries and explained more than 85% of the variance in the observed variation in transmissibility. We quantified country-specific mobility thresholds defined as the reduction in mobility necessary to expect a decline in new infections (R

Published

2020

13. Report 23: State-level tracking of COVID-19 in the United States

Author

Unwin, H, Mishra, S, Bradley, VC, Gandy, A, Vollmer, M, Mellan, T, Coupland, H, Ainslie, K, Whittaker, C, Ish-Horowicz, J, Filippi, S, Xi, X, Monod, M, Ratmann, O, Hutchinson, M, Valka, F, Zhu, H, Hawryluk, I, Milton, P, Baguelin, M, Boonyasiri, A, Brazeau, N, Cattarino, L, Charles, G, Cooper, L, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Djaafara, A, Dorigatti, I, Eales, O, Eaton, J, Van Elsland, S, Fitzjohn, R, Gaythorpe, K, Green, W, Hallett, T, Hinsley, W, Imai, N, Jeffrey, B, Knock, E, Laydon, D, Lees, J, Nedjati Gilani, G, Nouvellet, P, Okell, L, Ower, A, Parag, K, Siveroni, I, Thompson, H, Verity, R, Walker, P, Walters, C, Wang, Y, Watson, O, Whittles, L, Ghani, A, Ferguson, N, Riley, S, Donnelly, C, Bhatt, S, Flaxman, S, and Medical Research Council (MRC)

Subjects

Coronavirus, COVID19, COVID-19, United States

Abstract

our estimates show that the percentage of individuals that have been infected is 4.1% [3.7%-4.5%], with wide variation between states. For all states, even for the worst affected states, we estimate that less than a quarter of the population has been infected; in New York, for example, we estimate that 16.6% [12.8%-21.6%] of individuals have been infected to date. Our attack rates for New York are in line with those from recent serological studies [1] broadly supporting our choice of infection fatality rate. There is variation in the initial reproduction number, which is likely due to a range of factors; we find a strong association between the initial reproduction number with both population density (measured at the state level) and the chronological date when 10 cumulative deaths occurred (a crude estimate of the date of locally sustained transmission). Our estimates suggest that the epidemic is not under control in much of the US: as of 17 May 2020 the reproduction number is above the critical threshold (1.0) in 24 [95% CI: 20-30] states. Higher reproduction numbers are geographically clustered in the South and Midwest, where epidemics are still developing, while we estimate lower reproduction numbers in states that have already suffered high COVID-19 mortality (such as the Northeast). These estimates suggest that caution must be taken in loosening current restrictions if effective additional measures are not put in place. We predict that increased mobility following relaxation of social distancing will lead to resurgence of transmission, keeping all else constant. We predict that deaths over the next two-month period could exceed current cumulative deaths by greater than two-fold, if the relationship between mobility and transmission remains unchanged. Our results suggest that factors modulating transmission such as rapid testing, contact tracing and behavioural precautions are crucial to offset the rise of transmission associated with loosening of social distancing. Overall, we show that while all US states have substantially reduced their reproduction numbers, there is little evidence that any states are approaching herd immunity and thus the epidemic is close to over in any state.

Published

2020

14. Report 22: Equity in response to the COVID-19 pandemic: an assessment of the direct and indirect impacts on disadvantaged and vulnerable populations in low- and lower middle-income countries

Author

Winskill, P, Whittaker, C, Walker, P, Watson, O, Laydon, D, Imai, N, Cuomo-Dannenburg, G, Ainslie, K, Baguelin, M, Bhatt, S, Boonyasiri, A, Cattarino, L, Ciavarella, C, Cooper, L, Coupland, H, Cucunuba Perez, Z, Van Elsland, S, Fitzjohn, R, Flaxman, S, Gaythorpe, K, Green, W, Hallett, T, Hamlet, A, Hinsley, W, Knock, E, Lees, J, Mellan, T, Mishra, S, Nedjati Gilani, G, Nouvellet, P, Okell, L, Parag, K, Thompson, H, Unwin, H, Wang, Y, Whittles, L, Xi, X, Ferguson, N, Donnelly, C, Ghani, A, and Medical Research Council (MRC)

Subjects

Coronavirus, COVID19, COVID-19, Equity

Abstract

The impact of the COVID-19 pandemic in low-income settings is likely to be more severe due to limited healthcare capacity. Within these settings, however, there exists unfair or avoidable differences in health among different groups in society – health inequities – that mean that some groups are particularly at risk from the negative direct and indirect consequences of COVID-19. The structural determinants of these are often reflected in differences by income strata, with the poorest populations having limited access to preventative measures such as handwashing. Their more fragile income status will also mean that they are likely to be employed in occupations that are not amenable to social-distancing measures, thereby further reducing their ability to protect themselves from infection. Furthermore, these populations may also lack access to timely healthcare on becoming ill. We explore these relationships by using large-scale household surveys to quantify the differences in handwashing access, occupation and hospital access with respect to wealth status in low-income settings. We use a COVID-19 transmission model to demonstrate the impact of these differences. Our results demonstrate clear trends that the probability of death from COVID-19 increases with increasing poverty. On average, we estimate a 32.0% (2.5th-97.5th centile 8.0%-72.5%) increase in the probability of death in the poorest quintile compared to the wealthiest quintile from these three factors alone. We further explore how risk mediators and the indirect impacts of COVID-19 may also hit these same disadvantaged and vulnerable the hardest. We find that larger, inter-generational households that may hamper efforts to protect the elderly if social distancing are associated with lower-income countries and, within LMICs, lower wealth status. Poorer populations are also more susceptible to food security issues - with these populations having the highest levels under-nourishment whilst also being most dependent on their own food production. We show that timing of the COVID-19 epidemic in low-resource settings has the potential to interrupt planting and harvesting seasons for staple crops, thereby accentuating this vulnerability. These enhanced risks and key vulnerabilities – alongside the broader concerns surrounding displaced or conflict-affected populations - demonstrate the challenges that the most marginalised populations face during the ongoing COVID-19 pandemic.

Published

2020

15. Report 19: The potential impact of the COVID-19 epidemic on HIV, TB and malaria in low- and middle-income countries

Author

Hogan, A, Jewell, B, Sherrard-Smith, E, Vesga, J, Watson, O, Whittaker, C, Hamlet, A, Smith, J, Ainslie, K, Baguelin, M, Bhatt, S, Boonyasiri, A, Brazeau, N, Cattarino, L, Charles, G, Cooper, L, Coupland, H, Cuomo-Dannenburg, G, Dighe, A, Djaafara, A, Donnelly, C, Dorigatti, I, Eaton, J, Van Elsland, S, Fitzjohn, R, Fu, H, Gaythorpe, K, Green, W, Haw, D, Hayes, S, Hinsley, W, Imai, N, Knock, E, Laydon, D, Lees, J, Mangal, T, Mellan, T, Mishra, S, Nedjati Gilani, G, Nouvellet, P, Okell, L, Ower, A, Parag, K, Pickles, M, Stopard, I, Thompson, H, Unwin, H, Verity, R, Vollmer, M, Walters, C, Wang, H, Wang, Y, Whittles, L, Winskill, P, Xi, X, Ferguson, N, Churcher, T, Arinaminpathy, N, Ghani, A, Walker, P, Hallett, T, and Medical Research Council (MRC)

Abstract

COVID-19 has the potential to cause disruptions to health services in different ways; through the health system becoming overwhelmed with COVID-19 patients, through the intervention used to slow transmission of COVID-19 inhibiting access to preventative interventions and services, and through supplies of medicine being interrupted. We aim to quantify the extent to which such disruptions in services for HIV, TB and malaria in high burden low- and middle-income countries could lead to additional loss of life. In high burden settings, HIV, TB and malaria related deaths over 5 years may be increased by up to 10%, 20% and 36%, respectively, compared to if there were no COVID-19 epidemic. We estimate the greatest impact on HIV to be from interruption to ART, which may occur during a period of high or extremely high health system demand; for TB, we estimate the greatest impact is from reductions in timely diagnosis and treatment of new cases, which may result from a long period of COVID-19 suppression interventions; for malaria, we estimate that the greatest impact could come from reduced prevention activities including interruption of planned net campaigns, through all phases of the COVID-19 epidemic. In high burden settings, the impact of each type of disruption could be significant and lead to a loss of life-years over five years that is of the same order of magnitude as the direct impact from COVID-19 in places with a high burden of malaria and large HIV/TB epidemics. Maintaining the most critical prevention activities and healthcare services for HIV, TB and malaria could significantly reduce the overall impact of the COVID-19 epidemic.

Published

2020

16. Report 16: Role of testing in COVID-19 control

Author

Grassly, N, Pons Salort, M, Parker, E, White, P, Ainslie, K, Baguelin, M, Bhatt, S, Boonyasiri, A, Boyd, O, Brazeau, N, Cattarino, L, Ciavarella, C, Cooper, L, Coupland, H, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Dighe, A, Djaafara, A, Donnelly, C, Dorigatti, I, Van Elsland, S, Ferreira Do Nascimento, F, Fitzjohn, R, Fu, H, Gaythorpe, K, Geidelberg, L, Green, W, Hallett, T, Hamlet, A, Hayes, S, Hinsley, W, Imai, N, Jorgensen, D, Knock, E, Laydon, D, Lees, J, Mangal, T, Mellan, T, Mishra, S, Nedjati Gilani, G, Nouvellet, P, Okell, L, Ower, A, Parag, K, Pickles, M, Ragonnet-Cronin, M, Stopard, I, Thompson, H, Unwin, H, Verity, R, Vollmer, M, Volz, E, Walker, P, Walters, C, Wang, H, Wang, Y, Watson, O, Whittaker, C, Whittles, L, Winskill, P, Xi, X, Ferguson, N, and Medical Research Council (MRC)

Subjects

Coronavirus, COVID19, Testing, COVID-19

Abstract

The World Health Organization has called for increased molecular testing in response to the COVID-19 pandemic, but different countries have taken very different approaches. We used a simple mathematical model to investigate the potential effectiveness of alternative testing strategies for COVID-19 control. Weekly screening of healthcare workers (HCWs) and other at-risk groups using PCR or point-of-care tests for infection irrespective of symptoms is estimated to reduce their contribution to transmission by 25-33%, on top of reductions achieved by self-isolation following symptoms. Widespread PCR testing in the general population is unlikely to limit transmission more than contact-tracing and quarantine based on symptoms alone, but could allow earlier release of contacts from quarantine. Immunity passports based on tests for antibody or infection could support return to work but face significant technical, legal and ethical challenges. Testing is essential for pandemic surveillance but its direct contribution to the prevention of transmission is likely to be limited to patients, HCWs and other high-risk groups.

Published

2020

17. Report 13: Estimating the number of infections and the impact of non-pharmaceutical interventions on COVID-19 in 11 European countries

Author

Flaxman, S, Mishra, S, Gandy, A, Unwin, H, Coupland, H, Mellan, T, Zhu, H, Berah, T, Eaton, J, Perez Guzman, P, Schmit, N, Cilloni, L, Ainslie, K, Baguelin, M, Blake, I, Boonyasiri, A, Boyd, O, Cattarino, L, Ciavarella, C, Cooper, L, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Dighe, A, Djaafara, A, Dorigatti, I, Van Elsland, S, Fitzjohn, R, Fu, H, Gaythorpe, K, Geidelberg, L, Grassly, N, Green, W, Hallett, T, Hamlet, A, Hinsley, W, Jeffrey, B, Jorgensen, D, Knock, E, Laydon, D, Nedjati Gilani, G, Nouvellet, P, Parag, K, Siveroni, I, Thompson, H, Verity, R, Volz, E, Walters, C, Wang, H, Wang, Y, Watson, O, Winskill, P, Xi, X, Whittaker, C, Walker, P, Ghani, A, Donnelly, C, Riley, S, Okell, L, Vollmer, M, Ferguson, N, Bhatt, S, Medical Research Council (MRC), and The Royal Society

Subjects

Europe, COVID19, Non-pharmaceutical Interventions, Pneumonia, Viral, Coronavirus Infections, CoronaVirus

Abstract

Following the emergence of a novel coronavirus (SARS-CoV-2) and its spread outside of China, Europe is now experiencing large epidemics. In response, many European countries have implemented unprecedented non-pharmaceutical interventions including case isolation, the closure of schools and universities, banning of mass gatherings and/or public events, and most recently, widescale social distancing including local and national lockdowns. In this report, we use a semi-mechanistic Bayesian hierarchical model to attempt to infer the impact of these interventions across 11 European countries. Our methods assume that changes in the reproductive number – a measure of transmission - are an immediate response to these interventions being implemented rather than broader gradual changes in behaviour. Our model estimates these changes by calculating backwards from the deaths observed over time to estimate transmission that occurred several weeks prior, allowing for the time lag between infection and death. One of the key assumptions of the model is that each intervention has the same effect on the reproduction number across countries and over time. This allows us to leverage a greater amount of data across Europe to estimate these effects. It also means that our results are driven strongly by the data from countries with more advanced epidemics, and earlier interventions, such as Italy and Spain. We find that the slowing growth in daily reported deaths in Italy is consistent with a significant impact of interventions implemented several weeks earlier. In Italy, we estimate that the effective reproduction number, Rt, dropped to close to 1 around the time of lockdown (11th March), although with a high level of uncertainty. Overall, we estimate that countries have managed to reduce their reproduction number. Our estimates have wide credible intervals and contain 1 for countries that have implemented all interventions considered in our analysis. This means that the reproduction number may be above or below this value. With current interventions remaining in place to at least the end of March, we estimate that interventions across all 11 countries will have averted 59,000 deaths up to 31 March [95% credible interval 21,000-120,000]. Many more deaths will be averted through ensuring that interventions remain in place until transmission drops to low levels. We estimate that, across all 11 countries between 7 and 43 million individuals have been infected with SARS-CoV-2 up to 28th March, representing between 1.88% and 11.43% of the population. The proportion of the population infected to date – the attack rate - is estimated to be highest in Spain followed by Italy and lowest in Germany and Norway, reflecting the relative stages of the epidemics. Given the lag of 2-3 weeks between when transmission changes occur and when their impact can be observed in trends in mortality, for most of the countries considered here it remains too early to be certain that recent interventions have been effective. If interventions in countries at earlier stages of their epidemic, such as Germany or the UK, are more or less effective than they were in the countries with advanced epidemics, on which our estimates are largely based, or if interventions have improved or worsened over time, then our estimates of the reproduction number and deaths averted would change accordingly. It is therefore critical that the current interventions remain in place and trends in cases and deaths are closely monitored in the coming days and weeks to provide reassurance that transmission of SARS-Cov-2 is slowing.

Published

2020

18. Report 12: The global impact of COVID-19 and strategies for mitigation and suppression

Author

Walker, P, Whittaker, C, Watson, O, Baguelin, M, Ainslie, K, Bhatia, S, Bhatt, S, Boonyasiri, A, Boyd, O, Cattarino, L, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Dighe, A, Donnelly, C, Dorigatti, I, Van Elsland, S, Fitzjohn, R, Flaxman, S, Fu, H, Gaythorpe, K, Geidelberg, L, Grassly, N, Green, W, Hamlet, A, Hauck, K, Haw, D, Hayes, S, Hinsley, W, Imai, N, Jorgensen, D, Knock, E, Laydon, D, Mishra, S, Nedjati Gilani, G, Okell, L, Riley, S, Thompson, H, Unwin, H, Verity, R, Vollmer, M, Walters, C, Wang, H, Wang, Y, Winskill, P, Xi, X, Ferguson, N, Ghani, A, Medical Research Council (MRC), and The Royal Society

Subjects

Coronavirus, COVID19, Global Burden

Abstract

The world faces a severe and acute public health emergency due to the ongoing COVID-19 global pandemic. How individual countries respond in the coming weeks will be critical in influencing the trajectory of national epidemics. Here we combine data on age-specific contact patterns and COVID-19 severity to project the health impact of the pandemic in 202 countries. We compare predicted mortality impacts in the absence of interventions or spontaneous social distancing with what might be achieved with policies aimed at mitigating or suppressing transmission. Our estimates of mortality and healthcare demand are based on data from China and high-income countries; differences in underlying health conditions and healthcare system capacity will likely result in different patterns in low income settings. We estimate that in the absence of interventions, COVID-19 would have resulted in 7.0 billion infections and 40 million deaths globally this year. Mitigation strategies focussing on shielding the elderly (60% reduction in social contacts) and slowing but not interrupting transmission (40% reduction in social contacts for wider population) could reduce this burden by half, saving 20 million lives, but we predict that even in this scenario, health systems in all countries will be quickly overwhelmed. This effect is likely to be most severe in lower income settings where capacity is lowest: our mitigated scenarios lead to peak demand for critical care beds in a typical low-income setting outstripping supply by a factor of 25, in contrast to a typical high-income setting where this factor is 7. As a result, we anticipate that the true burden in low income settings pursuing mitigation strategies could be substantially higher than reflected in these estimates. Our analysis therefore suggests that healthcare demand can only be kept within manageable levels through the rapid adoption of public health measures (including testing and isolation of cases and wider social distancing measures) to suppress transmission, similar to those being adopted in many countries at the current time. If a suppression strategy is implemented early (at 0.2 deaths per 100,000 population per week) and sustained, then 38.7 million lives could be saved whilst if it is initiated when death numbers are higher (1.6 deaths per 100,000 population per week) then 30.7 million lives could be saved. Delays in implementing strategies to suppress transmission will lead to worse outcomes and fewer lives saved. We do not consider the wider social and economic costs of suppression, which will be high and may be disproportionately so in lower income settings. Moreover, suppression strategies will need to be maintained in some manner until vaccines or effective treatments become available to avoid the risk of later epidemics. Our analysis highlights the challenging decisions faced by all governments in the coming weeks and months, but demonstrates the extent to which rapid, decisive and collective action now could save millions of lives.

Published

2020

19. Report 11: Evidence of initial success for China exiting COVID-19 social distancing policy after achieving containment

Author

Ainslie, K, Walters, C, Fu, H, Bhatia, S, Wang, H, Baguelin, M, Bhatt, S, Boonyasiri, A, Boyd, O, Cattarino, L, Ciavarella, C, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Dighe, A, Dorigatti, I, Van Elsland, S, Fitzjohn, R, Gaythorpe, K, Geidelberg, L, Ghani, A, Green, W, Hamlet, A, Hauck, K, Hinsley, W, Imai, N, Jorgensen, D, Knock, E, Laydon, D, Nedjati Gilani, G, Okell, L, Siveroni, I, Thompson, H, Unwin, H, Verity, R, Vollmer, M, Walker, P, Wang, Y, Watson, O, Whittaker, C, Winskill, P, Xi, X, Donnelly, C, Ferguson, N, Riley, S, Medical Research Council (MRC), and The Royal Society

Subjects

Coronavirus, COVID19, Containment, Social Distancing

Abstract

The COVID-19 epidemic was declared a Global Pandemic by WHO on 11 March 2020. As of 20 March 2020, over 254,000 cases and 10,000 deaths had been reported worldwide. The outbreak began in the Chinese city of Wuhan in December 2019. In response to the fast-growing epidemic, China imposed strict social distancing in Wuhan on 23 January 2020 followed closely by similar measures in other provinces. At the peak of the outbreak in China (early February), there were between 2,000 and 4,000 new confirmed cases per day. For the first time since the outbreak began there have been no new confirmed cases caused by local transmission in China reported for five consecutive days up to 23 March 2020. This is an indication that the social distancing measures enacted in China have led to control of COVID-19 in China. These interventions have also impacted economic productivity in China, and the ability of the Chinese economy to resume without restarting the epidemic is not yet clear. Here, we estimate transmissibility from reported cases and compare those estimates with daily data on within-city movement, as a proxy for economic activity. Initially, within-city movement and transmission were very strongly correlated in the 5 provinces most affected by the epidemic and Beijing. However, that correlation is no longer apparent even though within-city movement has started to increase. A similar analysis for Hong Kong shows that intermediate levels of local activity can be maintained while avoiding a large outbreak. These results do not preclude future epidemics in China, nor do they allow us to estimate the maximum proportion of previous within-city activity that will be recovered in the medium term. However, they do suggest that after very intense social distancing which resulted in containment, China has successfully exited their stringent social distancing policy to some degree. Globally, China is at a more advanced stage of the pandemic. Policies implemented to reduce the spread of COVID-19 in China and the exiting strategies that followed can inform decision making processes for countries once containment is achieved.

Published

2020

20. Report 9: Impact of non-pharmaceutical interventions (NPIs) to reduce COVID19 mortality and healthcare demand

Author

Ferguson, N, Laydon, D, Nedjati Gilani, G, Imai, N, Ainslie, K, Baguelin, M, Bhatia, S, Boonyasiri, A, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Dighe, A, Dorigatti, I, Fu, H, Gaythorpe, K, Green, W, Hamlet, A, Hinsley, W, Okell, L, Van Elsland, S, Thompson, H, Verity, R, Volz, E, Wang, H, Wang, Y, Walker, P, Walters, C, Winskill, P, Whittaker, C, Donnelly, C, Riley, S, Ghani, A, Medical Research Council (MRC), and The Royal Society

Subjects

Coronavirus, COVID19, Non-pharmaceutical interventions, healthcare demand, Mortality

Abstract

The global impact of COVID-19 has been profound, and the public health threat it represents is the most serious seen in a respiratory virus since the 1918 H1N1 influenza pandemic. Here we present the results of epidemiological modelling which has informed policymaking in the UK and other countries in recent weeks. In the absence of a COVID-19 vaccine, we assess the potential role of a number of public health measures – so-called non-pharmaceutical interventions (NPIs) – aimed at reducing contact rates in the population and thereby reducing transmission of the virus. In the results presented here, we apply a previously published microsimulation model to two countries: the UK (Great Britain specifically) and the US. We conclude that the effectiveness of any one intervention in isolation is likely to be limited, requiring multiple interventions to be combined to have a substantial impact on transmission. Two fundamental strategies are possible: (a) mitigation, which focuses on slowing but not necessarily stopping epidemic spread – reducing peak healthcare demand while protecting those most at risk of severe disease from infection, and (b) suppression, which aims to reverse epidemic growth, reducing case numbers to low levels and maintaining that situation indefinitely. Each policy has major challenges. We find that that optimal mitigation policies (combining home isolation of suspect cases, home quarantine of those living in the same household as suspect cases, and social distancing of the elderly and others at most risk of severe disease) might reduce peak healthcare demand by 2/3 and deaths by half. However, the resulting mitigated epidemic would still likely result in hundreds of thousands of deaths and health systems (most notably intensive care units) being overwhelmed many times over. For countries able to achieve it, this leaves suppression as the preferred policy option. We show that in the UK and US context, suppression will minimally require a combination of social distancing of the entire population, home isolation of cases and household quarantine of their family members. This may need to be supplemented by school and university closures, though it should be recognised that such closures may have negative impacts on health systems due to increased absenteeism. The major challenge of suppression is that this type of intensive intervention package – or something equivalently effective at reducing transmission – will need to be maintained until a vaccine becomes available (potentially 18 months or more) – given that we predict that transmission will quickly rebound if interventions are relaxed. We show that intermittent social distancing – triggered by trends in disease surveillance – may allow interventions to be relaxed temporarily in relative short time windows, but measures will need to be reintroduced if or when case numbers rebound. Last, while experience in China and now South Korea show that suppression is possible in the short term, it remains to be seen whether it is possible long-term, and whether the social and economic costs of the interventions adopted thus far can be reduced.

Published

2020

21. Report 8: Symptom progression of COVID-19

Author

Gaythorpe, K, Imai, N, Cuomo-Dannenburg, G, Baguelin, M, Bhatia, S, Boonyasiri, A, Cori, A, Cucunuba Perez, Z, Dighe, A, Dorigatti, I, Fitzjohn, R, Fu, H, Green, W, Griffin, J, Hamlet, A, Hinsley, W, Hong, N, Kwun, M, Laydon, D, Nedjati Gilani, G, Okell, L, Riley, S, Thompson, H, Van Elsland, S, Verity, R, Volz, E, Walker, P, Wang, H, Wang, Y, Walters, C, Whittaker, C, Winskill, P, Xi, X, Donnelly, C, Ghani, A, Ferguson, N, Medical Research Council (MRC), and The Royal Society

Subjects

Coronavirus, COVID19, Symptom

Abstract

The COVID-19 epidemic was declared a Public Health Emergency of International Concern (PHEIC) by WHO on 30th January 2020 [1]. As of 8 March 2020, over 107,000 cases had been reported. Here, we use published and preprint studies of clinical characteristics of cases in mainland China as well as case studies of individuals from Hong Kong, Japan, Singapore and South Korea to examine the proportional occurrence of symptoms and the progression of symptoms through time. We find that in mainland China, where specific symptoms or disease presentation are reported, pneumonia is the most frequently mentioned, see figure 1. We found a more varied spectrum of severity in cases outside mainland China. In Hong Kong, Japan, Singapore and South Korea, fever was the most frequently reported symptom. In this latter group, presentation with pneumonia is not reported as frequently although it is more common in individuals over 60 years old. The average time from reported onset of first symptoms to the occurrence of specific symptoms or disease presentation, such as pneumonia or the use of mechanical ventilation, varied substantially. The average time to presentation with pneumonia is 5.88 days, and may be linked to testing at hospitalisation; fever is often reported at onset (where the mean time to develop fever is 0.77 days).

Published

2020

22. Report 7: Estimating infection prevalence in Wuhan City from repatriation flights

Author

Thompson, H, Imai, N, Dighe, A, Baguelin, M, Bhatia, S, Boonyasiri, A, Cori, A, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Dorigatti, I, Fitzjohn, R, Fu, H, Gaythorpe, K, Ghani, A, Green, W, Hamlet, A, Hinsley, W, Laydon, D, Nedjati Gilani, G, Okell, L, Riley, S, Van Elsland, S, Volz, E, Wang, H, Yuanrong, W, Whittaker, C, Xi, X, Donnelly, C, Ferguson, N, and Medical Research Council (MRC)

Subjects

Coronavirus, Prevalence, COVID-19, Repatriation flights, health care economics and organizations

Abstract

Since the end of January 2020, in response to the growing COVID-19 epidemic, 55 countries have repatriated over 8000 citizens from Wuhan City, China. In addition to quarantine measures for returning citizens, many countries implemented PCR screening to test for infection regardless of symptoms. These flights therefore give estimates of infection prevalence in Wuhan over time. Between 30th January and 1st February (close to the peak of the epidemic in Wuhan), infection prevalence was 0.87% (95% CI: 0.32% - 1.89%). As countries now start to repatriate citizens from Iran and northern Italy, information from repatriated citizens could help inform the level of response necessary to help control the outbreaks unfolding in newly affected areas.

Published

2020

23. Report 6: Relative sensitivity of international surveillance

Author

Bhatia, S, Imai, N, Cuomo-Dannenburg, G, Baguelin, M, Boonyasiri, A, Cori, A, Cucunuba Perez, Z, Dorigatti, I, Fitzjohn, R, Fu, H, Gaythorpe, K, Ghani, A, Hamlet, A, Hinsley, W, Laydon, D, Nedjati Gilani, G, Thompson, H, Okell, L, Riley, S, Van Elsland, S, Volz, E, Wang, H, Wang, Y, Whittaker, C, Xi, X, Donnelly, C, Ferguson, N, and Medical Research Council (MRC)

Subjects

Surveillance, COVID-19

Abstract

Since the start of the COVID-19 epidemic in late 2019, there are now 29 affected countries with over 1000 confirmed cases outside of mainland China. In previous reports, we estimated the likely epidemic size in Wuhan City based on air traffic volumes and the number of detected cases internationally. Here we analysed COVID-19 cases exported from mainland China to different regions and countries, comparing the country-specific rates of detected and confirmed cases per flight volume to estimate the relative sensitivity of surveillance in different countries. Although travel restrictions from Wuhan City and other cities across China may have reduced the absolute number of travellers to and from China, we estimated that about two thirds of COVID-19 cases exported from mainland China have remained undetected worldwide, potentially resulting in multiple chains of as yet undetected human-to-human transmission outside mainland China.

Published

2020

24. Report 5: Phylogenetic analysis of SARS-CoV-2

Author

Volz, E, Baguelin, M, Bhatia, S, Boonyasiri, A, Cori, A, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Donnelly, C, Dorigatti, I, Fitzjohn, R, Fu, H, Gaythorpe, K, Ghani, A, Hamlet, A, Hinsley, W, Imai, N, Laydon, D, Nedjati Gilani, G, Okell, L, Riley, S, Van Elsland, S, Wang, H, Wang, Y, Xi, X, Ferguson, N, Medical Research Council (MRC), and The Royal Society

Subjects

Phylogenetics, COVID-19

Abstract

Genetic diversity of SARS-CoV-2 (formerly 2019-nCoV), the virus which causes COVID-19, provides information about epidemic origins and the rate of epidemic growth. By analysing 53 SARS-CoV-2 whole genome sequences collected up to February 3, 2020, we find a strong association between the time of sample collection and accumulation of genetic diversity. Bayesian and maximum likelihood phylogenetic methods indicate that the virus was introduced into the human population in early December and has an epidemic doubling time of approximately seven days. Phylodynamic modelling provides an estimate of epidemic size through time. Precise estimates of epidemic size are not possible with current genetic data, but our analyses indicate evidence of substantial heterogeneity in the number of secondary infections caused by each case, as indicated by a high level of over-dispersion in the reproduction number. Larger numbers of more systematically sampled sequences – particularly from across China – will allow phylogenetic estimates of epidemic size and growth rate to be substantially refined.

Published

2020

25. Report 4: Severity of 2019-novel coronavirus (nCoV)

Author

Dorigatti, I, Okell, L, Cori, A, Imai, N, Baguelin, M, Bhatia, S, Boonyasiri, A, Cucunuba Perez, Z, Cuomo-Dannenburg, G, Fitzjohn, R, Fu, H, Gaythorpe, K, Hamlet, A, Hinsley, W, Hong, N, Kwun, M, Laydon, D, Nedjati Gilani, G, Riley, S, Van Elsland, S, Volz, E, Wang, H, Walters, C, Xi, X, Donnelly, C, Ghani, A, Ferguson, N, Medical Research Council (MRC), and The Royal Society

Subjects

CFR, COVID-19, Severity

Abstract

We present case fatality ratio (CFR) estimates for three strata of 2019-nCoV infections. For cases detected in Hubei, we estimate the CFR to be 18% (95% credible interval: 11%-81%). For cases detected in travellers outside mainland China, we obtain central estimates of the CFR in the range 1.2-5.6% depending on the statistical methods, with substantial uncertainty around these central values. Using estimates of underlying infection prevalence in Wuhan at the end of January derived from testing of passengers on repatriation flights to Japan and Germany, we adjusted the estimates of CFR from either the early epidemic in Hubei Province, or from cases reported outside mainland China, to obtain estimates of the overall CFR in all infections (asymptomatic or symptomatic) of approximately 1% (95% confidence interval 0.5%-4%). It is important to note that the differences in these estimates does not reflect underlying differences in disease severity between countries. CFRs seen in individual countries will vary depending on the sensitivity of different surveillance systems to detect cases of differing levels of severity and the clinical care offered to severely ill cases. All CFR estimates should be viewed cautiously at the current time as the sensitivity of surveillance of both deaths and cases in mainland China is unclear. Furthermore, all estimates rely on limited data on the typical time intervals from symptom onset to death or recovery which influences the CFR estimates.

Published

2020

26. Including PrEP for key populations in combination HIV prevention: a mathematical modelling analysis of Nairobi as a case-study

Author

Cremin, I, McKinnon, L, Kimani, J, Cherutich, P, Gakii, G, Muriuki, F, Kripke, K, Hecht, R, Kiragu, M, Smith, J, Hinsley, W, Gelmon, L, Hallett, T, and Medical Research Council (MRC)

Subjects

immune system diseases, virus diseases, 11 Medical and Health Sciences

Abstract

Background: The role of PrEP in combination HIV prevention remains uncertain. We aimed to identify an optimal portfolio of interventions to reduce HIV incidence for a given budget, and to identify the circumstances in which PrEP could be used in Nairobi, Kenya. Methods: A mathematical model was developed to represent HIV transmission among specific key populations (female sex workers (FSW), male sex workers (MSW), and men who have sex with men (MSM)) and among the wider population of Nairobi. The scale-up of existing interventions (condom promotion, anti-retroviral therapy (ART) and male circumcision) for key populations and the wider population as have occurred in Nairobi is represented. The model includes a detailed representation of a Pre-Exposure Prophylaxis (PrEP) intervention and is calibrated to prevalence and incidence estimates specific to key populations and the wider population. Findings: In the context of a declining epidemic overall but with a large sub-epidemic among MSM and MSW, an optimal prevention portfolio for Nairobi should focus on condom promotion for MSW and MSM in particular, followed by improved ART retention, earlier ART, and male circumcision as the budget allows. PrEP for MSW could enter an optimal portfolio at similar levels of spending to when earlier ART is included, however PrEP for MSM and FSW would be included only at much higher budgets. If PrEP for MSW cost as much $500, average annual spending on the interventions modelled would need to be less than $3·27 million for PrEP for MSW to be excluded from an optimal portfolio. Estimated costs per infection averted when providing PrEP to all FSW regardless of their risk of infection, and to high risk FSW only, are $65,160 (95% credible interval: $43,520 - $90,250) and $10,920 (95% credible interval: $4,700 - $51,560) respectively. Interpretation: PrEP could be a useful contribution to combination prevention, especially for underserved key populations in Nairobi. An ongoing demonstration project will provide important information regarding practical aspects of implementing PrEP for key populations in this setting.

Published

2016

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

Author

Garske, T, Cori, A, Ariyarajah, A, Blake, I, Dorigatti, I, Eckmanns, T, Fraser, C, Hinsley, W, Jombart, T, Mills, H, Nedjati-Gilani, G, Newton, E, Nouvellet, P, Perkins, D, Riley, S, Schumacher, D, Shah, A, Van Kerkhove, M, Dye, C, Ferguson, N, Donnelly, C, Medical Research Council (MRC), and National Institute for Health Research

Subjects

Life Sciences & Biomedicine - Other Topics, OUTCOMES, Evolutionary Biology, Science & Technology, FEATURES, CONAKRY, spatial heterogeneity, Ebola virus disease, case fatality ratio, severity, 11 Medical And Health Sciences, outlier detection, PERFORMANCE, 06 Biological Sciences, mortality, SIERRA-LEONE, SURVIVAL, GUINEA, EPIDEMIOLOGY, Life Sciences & Biomedicine, Biology, VIRUS DISEASE

Abstract

The 2013–2016 Ebola outbreak in West Africa is the largest on record with 28 616 confirmed, probable and suspected cases and 11 310 deaths officially recorded by 10 June 2016, the true burden probably considerably higher. The case fatality ratio (CFR: proportion of cases that are fatal) is a key indicator of disease severity useful for gauging the appropriate public health response and for evaluating treatment benefits, if estimated accurately. We analysed individual-level clinical outcome data from Guinea, Liberia and Sierra Leone officially reported to the World Health Organization. The overall mean CFR was 62.9% (95% CI: 61.9% to 64.0%) among confirmed cases with recorded clinical outcomes. Age was the most important modifier of survival probabilities, but country, stage of the epidemic and whether patients were hospitalized also played roles. We developed a statistical analysis to detect outliers in CFR between districts of residence and treatment centres (TCs), adjusting for known factors influencing survival and identified eight districts and three TCs with a CFR significantly different from the average. From the current dataset, we cannot determine whether the observed variation in CFR seen by district or treatment centre reflects real differences in survival, related to the quality of care or other factors or was caused by differences in reporting practices or case ascertainment.

Published

2016

28. Ebola Virus Disease among Male and Female Persons in West Africa

Author

Agua-Agum, J, Ariyarajah, A, Blake, IM, Cori, A, Donnelly, CA, Dorigatti, I, Dye, C, Eck-Manns, T, Ferguson, NM, Fraser, C, Garske, T, Hinsley, W, Jombart, T, Mills, HL, Nedjati-Gilani, G, Newton, E, Nouvellet, P, Perkins, D, Riley, S, Schumacher, D, Shah, A, Thomas, LJ, Van Kerkhove, MD, Medical Research Council (MRC), and National Institute for Health Research

Subjects

Male, 0301 basic medicine, medicine.medical_specialty, viruses, MEDLINE, Disease, medicine.disease_cause, Article, West africa, 03 medical and health sciences, Medicine, General & Internal, Sex Factors, Sex factors, General & Internal Medicine, medicine, Humans, Ebolavirus, Science & Technology, Ebola virus, business.industry, 11 Medical And Health Sciences, General Medicine, Hemorrhagic Fever, Ebola, Virology, Hospitalization, Survival Rate, Africa, Western, 030104 developmental biology, Family medicine, Female, business, Life Sciences & Biomedicine, WHO Ebola Response Team

Abstract

The Ebola virus has caused substantial illness in West Africa during the past 2 years. In this report, potential differences in the burden of illness between male and female persons are investigated.

Published

2016

29. In-service reliability demonstration testing

Author

Mealing, S.W., primary and Hinsley, W., additional

Published

2011

30. System assurance by in-service reliability evaluation

Author

Mealing, S.W., primary and Hinsley, W., additional

Published

2008

31. System assurance by in-service reliability evaluation

Author

Mealing, S.W., primary and Hinsley, W., additional

Published

2006

32. A simple approach to measure transmissibility and forecast incidence

Author

Nouvellet, P, Cori, A, Garske, T, Blake, I, Dorigatti, I, Hinsley, W, Jombart, T, Mills, H, Nedjati-Gilani, G, Kerkhove, V, Fraser, C, Donnelly, C, Ferguson, N, Riley, S, Wellcome Trust, Medical Research Council (MRC), National Institute for Health Research, and National Institutes of Health

Subjects

MCMC, Epidemiology, EPIDEMICS, Branching process, Microbiology, Communicable Diseases, Article, lcsh:Infectious and parasitic diseases, EBOLA-VIRUS DISEASE, Renewal equation, Virology, Humans, lcsh:RC109-216, Physics::Atmospheric and Oceanic Physics, WEST-AFRICA, Retrospective Studies, NUMBERS, Science & Technology, Incidence, Public Health, Environmental and Occupational Health, 1103 Clinical Sciences, Infectious Diseases, Rapid response, 1117 Public Health And Health Services, Parasitology, Life Sciences & Biomedicine, OUTBREAKS, Forecasting

Abstract

Highlights • Our simple approach relies on very few parameters and minimal assumptions • Subjective choice of best training period improved forecasts • Despites its simplicity, our model forecasted well under a range scenarios. • This approach can be a natural 'null model' for comparison with methods., Outbreaks of novel pathogens such as SARS, pandemic influenza and Ebola require substantial investments in reactive interventions, with consequent implementation plans sometimes revised on a weekly basis. Therefore, short-term forecasts of incidence are often of high priority. In light of the recent Ebola epidemic in West Africa, a forecasting exercise was convened by a network of infectious disease modellers. The challenge was to forecast unseen “future” simulated data for four different scenarios at five different time points. In a similar method to that used during the recent Ebola epidemic, we estimated current levels of transmissibility, over variable time-windows chosen in an ad hoc way. Current estimated transmissibility was then used to forecast near-future incidence. We performed well within the challenge and often produced accurate forecasts. A retrospective analysis showed that our subjective method for deciding on the window of time with which to estimate transmissibility often resulted in the optimal choice. However, when near-future trends deviated substantially from exponential patterns, the accuracy of our forecasts was reduced. This exercise highlights the urgent need for infectious disease modellers to develop more robust descriptions of processes – other than the widespread depletion of susceptible individuals – that produce non-exponential patterns of incidence.

33. Influenza: Making Privileged Data Public Response

Author

Christophe Fraser, Donnelly, C. A., Cauchemez, S., Hanage, W. P., Kerkhove, M. D., Hollingsworth, T. D., Griffin, J., Baggaley, R. F., Jenkins, H. E., Lyons, E. J., Jombart, T., Hinsley, W. R., Grassly, N. C., Balloux, F., Ghani, A. C., Rambaut, A., and Ferguson, N. M.

34. Modeling the role of environmental variables on the population dynamics of the malaria vector Anopheles gambiae sensu stricto

Author

Parham Paul E, Pople Diane, Christiansen-Jucht Céline, Lindsay Steve, Hinsley Wes, and Michael Edwin

Subjects

Malaria, Anopheles gambiae s.s., Temperature, Rainfall, Density-dependence, Mathematical modeling, Climate change, Arctic medicine. Tropical medicine, RC955-962, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background The impact of weather and climate on malaria transmission has attracted considerable attention in recent years, yet uncertainties around future disease trends under climate change remain. Mathematical models provide powerful tools for addressing such questions and understanding the implications for interventions and eradication strategies, but these require realistic modeling of the vector population dynamics and its response to environmental variables. Methods Published and unpublished field and experimental data are used to develop new formulations for modeling the relationships between key aspects of vector ecology and environmental variables. These relationships are integrated within a validated deterministic model of Anopheles gambiae s.s. population dynamics to provide a valuable tool for understanding vector response to biotic and abiotic variables. Results A novel, parsimonious framework for assessing the effects of rainfall, cloudiness, wind speed, desiccation, temperature, relative humidity and density-dependence on vector abundance is developed, allowing ease of construction, analysis, and integration into malaria transmission models. Model validation shows good agreement with longitudinal vector abundance data from Tanzania, suggesting that recent malaria reductions in certain areas of Africa could be due to changing environmental conditions affecting vector populations. Conclusions Mathematical models provide a powerful, explanatory means of understanding the role of environmental variables on mosquito populations and hence for predicting future malaria transmission under global change. The framework developed provides a valuable advance in this respect, but also highlights key research gaps that need to be resolved if we are to better understand future malaria risk in vulnerable communities.

Published

2012

35. Estimating the impact of vaccination: lessons learned in the first phase of the Vaccine Impact Modelling Consortium.

Author

Gaythorpe KAM, Li X, Clapham H, Dansereau E, Fitzjohn R, Hinsley W, Hogan D, Jit M, Mengistu T, Perkins TA, Portnoy A, Vynnycky E, Woodruff K, Ferguson NM, and Trotter CL

Subjects

Humans, Global Health, Immunization Programs, Models, Theoretical, Reproducibility of Results, Vaccines administration & dosage, Vaccination statistics & numerical data, Vaccination psychology

Abstract

Estimates of the global health impact of immunisation are important for quantifying historical benefits as well as planning future investments and strategy. The Vaccine Impact Modelling Consortium (VIMC) was established in 2016 to provide reliable estimates of the health impact of immunisation. In this article we examine the consortium in its first five-year phase. We detail how vaccine impact was defined and the methods used to estimate it as well as the technical infrastructure required to underpin robust reproducibility of the outputs. We highlight some of the applications of estimates to date, how these were communicated and what their effect were. Finally, we explore some of the lessons learnt and remaining challenges for estimating the impact of vaccines and forming effective modelling consortia then discuss how this may be addressed in the second phase of VIMC. Modelled estimates are not a replacement for surveillance; however, they can examine theoretical counterfactuals and highlight data gaps to complement other activities. VIMC has implemented strategies to produce robust, standardised estimates of immunisation impact. But through the first phase of the consortium, critical lessons have been learnt both on the technical infrastructure and the effective engagement with modellers and stakeholders. To be successful, a productive dialogue with estimate consumers, producers and stakeholders needs to be underpinned by a rigorous and transparent analytical framework as well as an approach for building expertise in the short and long term., Competing Interests: Competing interests: KAMG, XL, HC, ED, RF, WH, DH, MJ, TM, TAP, AP, EV, KW, NMF, CLT, received funding from Gavi, BMGF and/or the Wellcome Trust via VIMC during the course of the study. The authors declare no other competing interests., (Copyright: © 2024 Gaythorpe KAM et al.)

Published

2024

36. The impact of health inequity on spatial variation of COVID-19 transmission in England.

Author

Rawson T, Hinsley W, Sonabend R, Semenova E, Cori A, and Ferguson NM

Subjects

Humans, England epidemiology, Pandemics statistics & numerical data, Socioeconomic Factors, Health Status Disparities, Models, Statistical, COVID-19 transmission, COVID-19 epidemiology, Bayes Theorem, SARS-CoV-2

Abstract

Considerable spatial heterogeneity has been observed in COVID-19 transmission across administrative areas of England throughout the pandemic. This study investigates what drives these differences. We constructed a probabilistic case count model for 306 administrative areas of England across 95 weeks, fit using a Bayesian evidence synthesis framework. We incorporate the impact of acquired immunity, of spatial exportation of cases, and 16 spatially-varying socio-economic, socio-demographic, health, and mobility variables. Model comparison assesses the relative contributions of these respective mechanisms. We find that spatially-varying and time-varying differences in week-to-week transmission were definitively associated with differences in: time spent at home, variant-of-concern proportion, and adult social care funding. However, model comparison demonstrates that the impact of these terms is negligible compared to the role of spatial exportation between administrative areas. While these results confirm the impact of some, but not all, static measures of spatially-varying inequity in England, our work corroborates the finding that observed differences in disease transmission during the pandemic were predominantly driven by underlying epidemiological factors rather than aggregated metrics of demography and health inequity between areas. Further work is required to assess how health inequity more broadly contributes to these epidemiological factors., Competing Interests: I have read the journal’s policy and the authors of this manuscript have the following competing interests: AC has received payment from Pfizer for teaching of mathematical modelling of infectious diseases. All other authors declare no competing interests., (Copyright: © 2024 Rawson et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

37. Estimating the health effects of COVID-19-related immunisation disruptions in 112 countries during 2020-30: a modelling study.

Author

Hartner AM, Li X, Echeverria-Londono S, Roth J, Abbas K, Auzenbergs M, de Villiers MJ, Ferrari MJ, Fraser K, Fu H, Hallett T, Hinsley W, Jit M, Karachaliou A, Moore SM, Nayagam S, Papadopoulos T, Perkins TA, Portnoy A, Minh QT, Vynnycky E, Winter AK, Burrows H, Chen C, Clapham HE, Deshpande A, Hauryski S, Huber J, Jean K, Kim C, Kim JH, Koh J, Lopman BA, Pitzer VE, Tam Y, Lambach P, Sim SY, Woodruff K, Ferguson NM, Trotter CL, and Gaythorpe KAM

Subjects

Humans, Pandemics, Vaccination, Immunization, Papillomavirus Infections prevention & control, Vaccine-Preventable Diseases, Yellow Fever, COVID-19 epidemiology, COVID-19 prevention & control, Rubella, Papillomavirus Vaccines, Measles, Hepatitis B drug therapy, Meningitis

Abstract

Background: There have been declines in global immunisation coverage due to the COVID-19 pandemic. Recovery has begun but is geographically variable. This disruption has led to under-immunised cohorts and interrupted progress in reducing vaccine-preventable disease burden. There have, so far, been few studies of the effects of coverage disruption on vaccine effects. We aimed to quantify the effects of vaccine-coverage disruption on routine and campaign immunisation services, identify cohorts and regions that could particularly benefit from catch-up activities, and establish if losses in effect could be recovered., Methods: For this modelling study, we used modelling groups from the Vaccine Impact Modelling Consortium from 112 low-income and middle-income countries to estimate vaccine effect for 14 pathogens. One set of modelling estimates used vaccine-coverage data from 1937 to 2021 for a subset of vaccine-preventable, outbreak-prone or priority diseases (ie, measles, rubella, hepatitis B, human papillomavirus [HPV], meningitis A, and yellow fever) to examine mitigation measures, hereafter referred to as recovery runs. The second set of estimates were conducted with vaccine-coverage data from 1937 to 2020, used to calculate effect ratios (ie, the burden averted per dose) for all 14 included vaccines and diseases, hereafter referred to as full runs. Both runs were modelled from Jan 1, 2000, to Dec 31, 2100. Countries were included if they were in the Gavi, the Vaccine Alliance portfolio; had notable burden; or had notable strategic vaccination activities. These countries represented the majority of global vaccine-preventable disease burden. Vaccine coverage was informed by historical estimates from WHO-UNICEF Estimates of National Immunization Coverage and the immunisation repository of WHO for data up to and including 2021. From 2022 onwards, we estimated coverage on the basis of guidance about campaign frequency, non-linear assumptions about the recovery of routine immunisation to pre-disruption magnitude, and 2030 endpoints informed by the WHO Immunization Agenda 2030 aims and expert consultation. We examined three main scenarios: no disruption, baseline recovery, and baseline recovery and catch-up., Findings: We estimated that disruption to measles, rubella, HPV, hepatitis B, meningitis A, and yellow fever vaccination could lead to 49 119 additional deaths (95% credible interval [CrI] 17 248-134 941) during calendar years 2020-30, largely due to measles. For years of vaccination 2020-30 for all 14 pathogens, disruption could lead to a 2·66% (95% CrI 2·52-2·81) reduction in long-term effect from 37 378 194 deaths averted (34 450 249-40 241 202) to 36 410 559 deaths averted (33 515 397-39 241 799). We estimated that catch-up activities could avert 78·9% (40·4-151·4) of excess deaths between calendar years 2023 and 2030 (ie, 18 900 [7037-60 223] of 25 356 [9859-75 073])., Interpretation: Our results highlight the importance of the timing of catch-up activities, considering estimated burden to improve vaccine coverage in affected cohorts. We estimated that mitigation measures for measles and yellow fever were particularly effective at reducing excess burden in the short term. Additionally, the high long-term effect of HPV vaccine as an important cervical-cancer prevention tool warrants continued immunisation efforts after disruption., Funding: The Vaccine Impact Modelling Consortium, funded by Gavi, the Vaccine Alliance and the Bill & Melinda Gates Foundation., Translations: For the Arabic, Chinese, French, Portguese and Spanish translations of the abstract see Supplementary Materials section., Competing Interests: Declaration of interests A-MH, XL, SE-L, JR, KA, MA, MJdV, MJF, KF, HF, TH, MJ, AK, SMM, SN, TP, TAP, AP, QTM, EV, AKW, HB, CC, HEC, AD, SH, JH, KJ, CK, J-HK, JK, BAL, VEP, YT, KW, NMF, CLT, and KAMG received funding from Gavi, the Vaccine Alliance and the Bill & Melinda Gates Foundation via the Vaccine Impact Modelling Consortium (VIMC) during the study. A-MH, JR, SE-L, XL, SN, MJdV, TH, WH, KW, NMF, CLT, and KAMG receive funding from the Medical Research Council Centre for Global Infectious Disease Analysis (reference MR/R015600/1), which is jointly funded by the UK Medical Research Council and the UK Foreign, Commonwealth, and Development Office under a concordant agreement, and is also part of the European and Developing Countries Clinical Trials Partnership programme supported by the EU. A-MH, JR, SE-L, XL, SN, MJdV, TH, WH, KW, NMF, CLT, and KAMG receive funding from Community Jameel. A-MH is supported by the German Federal Ministry of Education and Research (grant 01LN2210A) and declares stock options in BIONTECH. CLT received payment for advice from GlaxoSmithKline. KA is supported by the Japan Agency for Medical Research and Development (JP223fa627004). KAMG received a speaker fee from Sanofi Pasteur. SN receives consulting fees from WHO. VEP is a member of the WHO Immunization and Implementation Research Advisory Committee. BAL receives personal fees from Epidemiologic Research and Methods and Hillevax. SMM receives consultant fees from Emergent Biosolutions. NMF receives grant funding from Janssen Pharmaceuticals, UK Research and Innovation, and the UK National Institute for Health and Care Research; declares consulting fees from the World Bank, WHO, and Gavi; receives travel expenses for WHO meetings; was on an advisory board for Takeda; and is a senior editor for eLife. All other authors declare no competing interests., (Copyright © 2024 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

2024

38. Author Correction: Epidemiological drivers of transmissibility and severity of SARS-CoV-2 in England.

Author

Perez-Guzman PN, Knock E, Imai N, Rawson T, Santoni CN, Alcada J, Whittles LK, Thekke Kanapram D, Sonabend R, Gaythorpe KAM, Hinsley W, FitzJohn RG, Volz E, Verity R, Ferguson NM, Cori A, and Baguelin M

Published

2023

39. Epidemiological drivers of transmissibility and severity of SARS-CoV-2 in England.

Author

Perez-Guzman PN, Knock E, Imai N, Rawson T, Santoni CN, Alcada J, Whittles LK, Thekke Kanapram D, Sonabend R, Gaythorpe KAM, Hinsley W, FitzJohn RG, Volz E, Verity R, Ferguson NM, Cori A, and Baguelin M

Subjects

Humans, Bayes Theorem, England epidemiology, SARS-CoV-2 genetics, COVID-19 epidemiology

Abstract

As the SARS-CoV-2 pandemic progressed, distinct variants emerged and dominated in England. These variants, Wildtype, Alpha, Delta, and Omicron were characterized by variations in transmissibility and severity. We used a robust mathematical model and Bayesian inference framework to analyse epidemiological surveillance data from England. We quantified the impact of non-pharmaceutical interventions (NPIs), therapeutics, and vaccination on virus transmission and severity. Each successive variant had a higher intrinsic transmissibility. Omicron (BA.1) had the highest basic reproduction number at 8.3 (95% credible interval (CrI) 7.7-8.8). Varying levels of NPIs were crucial in controlling virus transmission until population immunity accumulated. Immune escape properties of Omicron decreased effective levels of immunity in the population by a third. Furthermore, in contrast to previous studies, we found Alpha had the highest basic infection fatality ratio (2.9%, 95% CrI 2.7-3.2), followed by Delta (2.2%, 95% CrI 2.0-2.4), Wildtype (1.2%, 95% CrI 1.1-1.2), and Omicron (0.7%, 95% CrI 0.6-0.8). Our findings highlight the importance of continued surveillance. Long-term strategies for monitoring and maintaining effective immunity against SARS-CoV-2 are critical to inform the role of NPIs to effectively manage future variants with potentially higher intrinsic transmissibility and severe outcomes., (© 2023. The Author(s).)

Published

2023

40. Data pipelines in a public health emergency: The human in the machine.

Author

Gaythorpe KAM, Fitzjohn RG, Hinsley W, Imai N, Knock ES, Perez Guzman PN, Djaafara B, Fraser K, Baguelin M, and Ferguson NM

Subjects

Humans, Public Health, Reproducibility of Results, Disease Outbreaks, COVID-19 epidemiology

Abstract

In an emergency epidemic response, data providers supply data on a best-faith effort to modellers and analysts who are typically the end user of data collected for other primary purposes such as to inform patient care. Thus, modellers who analyse secondary data have limited ability to influence what is captured. During an emergency response, models themselves are often under constant development and require both stability in their data inputs and flexibility to incorporate new inputs as novel data sources become available. This dynamic landscape is challenging to work with. Here we outline a data pipeline used in the ongoing COVID-19 response in the UK that aims to address these issues. A data pipeline is a sequence of steps to carry the raw data through to a processed and useable model input, along with the appropriate metadata and context. In ours, each data type had an individual processing report, designed to produce outputs that could be easily combined and used downstream. Automated checks were in-built and added as new pathologies emerged. These cleaned outputs were collated at different geographic levels to provide standardised datasets. Finally, a human validation step was an essential component of the analysis pathway and permitted more nuanced issues to be captured. This framework allowed the pipeline to grow in complexity and volume and facilitated the diverse range of modelling approaches employed by researchers. Additionally, every report or modelling output could be traced back to the specific data version that informed it ensuring reproducibility of results. Our approach has been used to facilitate fast-paced analysis and has evolved over time. Our framework and its aspirations are applicable to many settings beyond COVID-19 data, for example for other outbreaks such as Ebola, or where routine and regular analyses are required., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2023

41. Quantifying the effect of delaying the second COVID-19 vaccine dose in England: a mathematical modelling study.

Author

Imai N, Rawson T, Knock ES, Sonabend R, Elmaci Y, Perez-Guzman PN, Whittles LK, Kanapram DT, Gaythorpe KAM, Hinsley W, Djaafara BA, Wang H, Fraser K, FitzJohn RG, Hogan AB, Doohan P, Ghani AC, Ferguson NM, Baguelin M, and Cori A

Subjects

Humans, Aged, Infant, Bayes Theorem, Seroepidemiologic Studies, Australia, SARS-CoV-2, England, COVID-19 Vaccines, COVID-19

Abstract

Background: The UK was the first country to start national COVID-19 vaccination programmes, initially administering doses 3 weeks apart. However, early evidence of high vaccine effectiveness after the first dose and the emergence of the SARS-CoV-2 alpha variant prompted the UK to extend the interval between doses to 12 weeks. In this study, we aimed to quantify the effect of delaying the second vaccine dose in England., Methods: We used a previously described model of SARS-CoV-2 transmission, calibrated to COVID-19 surveillance data from England, including hospital admissions, hospital occupancy, seroprevalence data, and population-level PCR testing data, using a Bayesian evidence-synthesis framework. We modelled and compared the epidemic trajectory in the counterfactual scenario in which vaccine doses were administered 3 weeks apart against the real reported vaccine roll-out schedule of 12 weeks. We estimated and compared the resulting numbers of daily infections, hospital admissions, and deaths. In sensitivity analyses, we investigated scenarios spanning a range of vaccine effectiveness and waning assumptions., Findings: In the period from Dec 8, 2020, to Sept 13, 2021, the number of individuals who received a first vaccine dose was higher under the 12-week strategy than the 3-week strategy. For this period, we estimated that delaying the interval between the first and second COVID-19 vaccine doses from 3 to 12 weeks averted a median (calculated as the median of the posterior sample) of 58 000 COVID-19 hospital admissions (291 000 cumulative hospitalisations [95% credible interval 275 000-319 000] under the 3-week strategy vs 233 000 [229 000-238 000] under the 12-week strategy) and 10 100 deaths (64 800 deaths [60 200-68 900] vs 54 700 [52 800-55 600]). Similarly, we estimated that the 3-week strategy would have resulted in more infections compared with the 12-week strategy. Across all sensitivity analyses the 3-week strategy resulted in a greater number of hospital admissions. In results by age group, the 12-week strategy led to more hospitalisations and deaths in older people in spring 2021, but fewer following the emergence of the delta variant during summer 2021., Interpretation: England's delayed-second-dose vaccination strategy was informed by early real-world data on vaccine effectiveness in the context of limited vaccine supplies in a growing epidemic. Our study shows that rapidly providing partial (single-dose) vaccine-induced protection to a larger proportion of the population was successful in reducing the burden of COVID-19 hospitalisations and deaths overall., Funding: UK National Institute for Health Research; UK Medical Research Council; Community Jameel; Wellcome Trust; UK Foreign, Commonwealth and Development Office; Australian National Health and Medical Research Council; and EU., Competing Interests: Declaration of interests AC has received payment from Pfizer for teaching of mathematical modelling of infectious diseases. KAMG has received honoraria from Wellcome Genome Campus for lectures. LKW has received consultancy payments from the Wellcome Trust. ABH has received consultancy payments from WHO for COVID-19-related work; provides advice on COVID-19 modelling to the New South Wales Ministry of Health, Australia; and was previously engaged by Pfizer to advise on modelling of RSV vaccination strategies, for which she received no financial compensation. RS and NI are currently employed by the Wellcome Trust. 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

42. Misclassification bias in estimating clinical severity of SARS-CoV-2 variants - Authors' reply.

Author

Nyberg T, Ferguson NM, Blake J, Hinsley W, Bhatt S, De Angelis D, Thelwall S, and Presanis AM

Subjects

Humans, COVID-19, SARS-CoV-2 genetics

Published

2022

43. Comparative analysis of the risks of hospitalisation and death associated with SARS-CoV-2 omicron (B.1.1.529) and delta (B.1.617.2) variants in England: a cohort study.

Author

Nyberg T, Ferguson NM, Nash SG, Webster HH, Flaxman S, Andrews N, Hinsley W, Bernal JL, Kall M, Bhatt S, Blomquist P, Zaidi A, Volz E, Aziz NA, Harman K, Funk S, Abbott S, Hope R, Charlett A, Chand M, Ghani AC, Seaman SR, Dabrera G, De Angelis D, Presanis AM, and Thelwall S

Subjects

Cohort Studies, England epidemiology, Hospitalization, Humans, Vaccines, Synthetic, mRNA Vaccines, COVID-19 epidemiology, COVID-19 prevention & control, SARS-CoV-2

Abstract

Background: The omicron variant (B.1.1.529) of SARS-CoV-2 has demonstrated partial vaccine escape and high transmissibility, with early studies indicating lower severity of infection than that of the delta variant (B.1.617.2). We aimed to better characterise omicron severity relative to delta by assessing the relative risk of hospital attendance, hospital admission, or death in a large national cohort., Methods: Individual-level data on laboratory-confirmed COVID-19 cases resident in England between Nov 29, 2021, and Jan 9, 2022, were linked to routine datasets on vaccination status, hospital attendance and admission, and mortality. The relative risk of hospital attendance or admission within 14 days, or death within 28 days after confirmed infection, was estimated using proportional hazards regression. Analyses were stratified by test date, 10-year age band, ethnicity, residential region, and vaccination status, and were further adjusted for sex, index of multiple deprivation decile, evidence of a previous infection, and year of age within each age band. A secondary analysis estimated variant-specific and vaccine-specific vaccine effectiveness and the intrinsic relative severity of omicron infection compared with delta (ie, the relative risk in unvaccinated cases)., Findings: The adjusted hazard ratio (HR) of hospital attendance (not necessarily resulting in admission) with omicron compared with delta was 0·56 (95% CI 0·54-0·58); for hospital admission and death, HR estimates were 0·41 (0·39-0·43) and 0·31 (0·26-0·37), respectively. Omicron versus delta HR estimates varied with age for all endpoints examined. The adjusted HR for hospital admission was 1·10 (0·85-1·42) in those younger than 10 years, decreasing to 0·25 (0·21-0·30) in 60-69-year-olds, and then increasing to 0·47 (0·40-0·56) in those aged at least 80 years. For both variants, past infection gave some protection against death both in vaccinated (HR 0·47 [0·32-0·68]) and unvaccinated (0·18 [0·06-0·57]) cases. In vaccinated cases, past infection offered no additional protection against hospital admission beyond that provided by vaccination (HR 0·96 [0·88-1·04]); however, for unvaccinated cases, past infection gave moderate protection (HR 0·55 [0·48-0·63]). Omicron versus delta HR estimates were lower for hospital admission (0·30 [0·28-0·32]) in unvaccinated cases than the corresponding HR estimated for all cases in the primary analysis. Booster vaccination with an mRNA vaccine was highly protective against hospitalisation and death in omicron cases (HR for hospital admission 8-11 weeks post-booster vs unvaccinated: 0·22 [0·20-0·24]), with the protection afforded after a booster not being affected by the vaccine used for doses 1 and 2., Interpretation: The risk of severe outcomes following SARS-CoV-2 infection is substantially lower for omicron than for delta, with higher reductions for more severe endpoints and significant variation with age. Underlying the observed risks is a larger reduction in intrinsic severity (in unvaccinated individuals) counterbalanced by a reduction in vaccine effectiveness. Documented previous SARS-CoV-2 infection offered some protection against hospitalisation and high protection against death in unvaccinated individuals, but only offered additional protection in vaccinated individuals for the death endpoint. Booster vaccination with mRNA vaccines maintains over 70% protection against hospitalisation and death in breakthrough confirmed omicron infections., Funding: Medical Research Council, UK Research and Innovation, Department of Health and Social Care, National Institute for Health Research, Community Jameel, and Engineering and Physical Sciences Research Council., Competing Interests: Declaration of interests GD declares that his employer UK Health Security Agency (previously operating as Public Health England) received funding from GlaxoSmithKline for a research project related to influenza antiviral treatment. This preceded and had no relation to COVID-19, and GD had no role in and received no funding from the project. All other authors declare no competing interests., (Copyright © 2022 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

2022

44. Estimating the number of undetected COVID-19 cases among travellers from mainland China.

Author

Bhatia S, Imai N, Cuomo-Dannenburg G, Baguelin M, Boonyasiri A, Cori A, Cucunubá Z, Dorigatti I, FitzJohn R, Fu H, Gaythorpe K, Ghani A, Hamlet A, Hinsley W, Laydon D, Nedjati-Gilani G, Okell L, Riley S, Thompson H, van Elsland S, Volz E, Wang H, Wang Y, Whittaker C, Xi X, Donnelly CA, and Ferguson NM

Abstract

Background:  As of August 2021, every region of the world has been affected by the COVID-19 pandemic, with more than 196,000,000 cases worldwide. Methods: We analysed COVID-19 cases among travellers from mainland China to different regions and countries, comparing the region- and country-specific rates of detected and confirmed cases per flight volume to estimate the relative sensitivity of surveillance in different regions and countries. Results: Although travel restrictions from Wuhan City and other cities across China may have reduced the absolute number of travellers to and from China, we estimated that up to 70% (95% CI: 54% - 80%) of imported cases could remain undetected relative to the sensitivity of surveillance in Singapore. The percentage of undetected imported cases rises to 75% (95% CI 66% - 82%) when comparing to the surveillance sensitivity in multiple countries. Conclusions:  Our analysis shows that a large number of COVID-19 cases remain undetected across the world.   These undetected cases potentially resulted in multiple chains of human-to-human transmission outside mainland China., Competing Interests: No competing interests were disclosed., (Copyright: © 2021 Bhatia S et al.)

Published

2021

45. Exploring relationships between drought and epidemic cholera in Africa using generalised linear models.

Author

Charnley GEC, Kelman I, Green N, Hinsley W, Gaythorpe KAM, and Murray KA

Subjects

Africa epidemiology, Disease Outbreaks, Droughts, Humans, Linear Models, Cholera epidemiology, Epidemics

Abstract

Background: Temperature and precipitation are known to affect Vibrio cholerae outbreaks. Despite this, the impact of drought on outbreaks has been largely understudied. Africa is both drought and cholera prone and more research is needed in Africa to understand cholera dynamics in relation to drought., Methods: Here, we analyse a range of environmental and socioeconomic covariates and fit generalised linear models to publicly available national data, to test for associations with several indices of drought and make cholera outbreak projections to 2070 under three scenarios of global change, reflecting varying trajectories of CO 2 emissions, socio-economic development, and population growth., Results: The best-fit model implies that drought is a significant risk factor for African cholera outbreaks, alongside positive effects of population, temperature and poverty and a negative effect of freshwater withdrawal. The projections show that following stringent emissions pathways and expanding sustainable development may reduce cholera outbreak occurrence in Africa, although these changes were spatially heterogeneous., Conclusions: Despite an effect of drought in explaining recent cholera outbreaks, future projections highlighted the potential for sustainable development gains to offset drought-related impacts on cholera risk. Future work should build on this research investigating the impacts of drought on cholera on a finer spatial scale and potential non-linear relationships, especially in high-burden countries which saw little cholera change in the scenario analysis., (© 2021. The Author(s).)

Published

2021

46. Non-pharmaceutical interventions, vaccination, and the SARS-CoV-2 delta variant in England: a mathematical modelling study.

Author

Sonabend R, Whittles LK, Imai N, Perez-Guzman PN, Knock ES, Rawson T, Gaythorpe KAM, Djaafara BA, Hinsley W, FitzJohn RG, Lees JA, Kanapram DT, Volz EM, Ghani AC, Ferguson NM, Baguelin M, and Cori A

Subjects

COVID-19 epidemiology, COVID-19 mortality, England epidemiology, Hospital Mortality trends, Hospitalization statistics & numerical data, Humans, Models, Theoretical, Patient Admission statistics & numerical data, COVID-19 prevention & control, COVID-19 transmission, COVID-19 Vaccines administration & dosage, Communicable Disease Control organization & administration, SARS-CoV-2, Vaccination Coverage organization & administration

Abstract

Background: England's COVID-19 roadmap out of lockdown policy set out the timeline and conditions for the stepwise lifting of non-pharmaceutical interventions (NPIs) as vaccination roll-out continued, with step one starting on March 8, 2021. In this study, we assess the roadmap, the impact of the delta (B.1.617.2) variant of SARS-CoV-2, and potential future epidemic trajectories., Methods: This mathematical modelling study was done to assess the UK Government's four-step process to easing lockdown restrictions in England, UK. We extended a previously described model of SARS-CoV-2 transmission to incorporate vaccination and multi-strain dynamics to explicitly capture the emergence of the delta variant. We calibrated the model to English surveillance data, including hospital admissions, hospital occupancy, seroprevalence data, and population-level PCR testing data using a Bayesian evidence synthesis framework, then modelled the potential trajectory of the epidemic for a range of different schedules for relaxing NPIs. We estimated the resulting number of daily infections and hospital admissions, and daily and cumulative deaths. Three scenarios spanning a range of optimistic to pessimistic vaccine effectiveness, waning natural immunity, and cross-protection from previous infections were investigated. We also considered three levels of mixing after the lifting of restrictions., Findings: The roadmap policy was successful in offsetting the increased transmission resulting from lifting NPIs starting on March 8, 2021, with increasing population immunity through vaccination. However, because of the emergence of the delta variant, with an estimated transmission advantage of 76% (95% credible interval [95% CrI] 69-83) over alpha, fully lifting NPIs on June 21, 2021, as originally planned might have led to 3900 (95% CrI 1500-5700) peak daily hospital admissions under our central parameter scenario. Delaying until July 19, 2021, reduced peak hospital admissions by three fold to 1400 (95% CrI 700-1700) per day. There was substantial uncertainty in the epidemic trajectory, with particular sensitivity to the transmissibility of delta, level of mixing, and estimates of vaccine effectiveness., Interpretation: Our findings show that the risk of a large wave of COVID-19 hospital admissions resulting from lifting NPIs can be substantially mitigated if the timing of NPI relaxation is carefully balanced against vaccination coverage. However, with the delta variant, it might not be possible to fully lift NPIs without a third wave of hospital admissions and deaths, even if vaccination coverage is high. Variants of concern, their transmissibility, vaccine uptake, and vaccine effectiveness must be carefully monitored as countries relax pandemic control measures., Funding: National Institute for Health Research, UK Medical Research Council, Wellcome Trust, and UK Foreign, Commonwealth and Development Office., Competing Interests: Declaration of interests AC has received payment from Pfizer for teaching of mathematical modelling of infectious diseases. KAMG has received honoraria from Wellcome Genome Campus for lectures and salary support from the Bill & Melinda Gates Foundation and Gavi, the Vaccine Alliance, through Imperial College London for work outside this study. All other authors declare no competing interests., (Copyright © 2021 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

2021

47. Key epidemiological drivers and impact of interventions in the 2020 SARS-CoV-2 epidemic in England.

Author

Knock ES, Whittles LK, Lees JA, Perez-Guzman PN, Verity R, FitzJohn RG, Gaythorpe KAM, Imai N, Hinsley W, Okell LC, Rosello A, Kantas N, Walters CE, Bhatia S, Watson OJ, Whittaker C, Cattarino L, Boonyasiri A, Djaafara BA, Fraser K, Fu H, Wang H, Xi X, Donnelly CA, Jauneikaite E, Laydon DJ, White PJ, Ghani AC, Ferguson NM, Cori A, and Baguelin M

Subjects

Aged, Communicable Disease Control, England epidemiology, Humans, SARS-CoV-2, COVID-19, Epidemics

Abstract

We fitted a model of SARS-CoV-2 transmission in care homes and the community to regional surveillance data for England. Compared with other approaches, our model provides a synthesis of multiple surveillance data streams into a single coherent modeling framework, allowing transmission and severity to be disentangled from features of the surveillance system. Of the control measures implemented, only national lockdown brought the reproduction number ( R t eff ) below 1 consistently; if introduced 1 week earlier, it could have reduced deaths in the first wave from an estimated 48,600 to 25,600 [95% credible interval (CrI): 15,900 to 38,400]. The infection fatality ratio decreased from 1.00% (95% CrI: 0.85 to 1.21%) to 0.79% (95% CrI: 0.63 to 0.99%), suggesting improved clinical care. The infection fatality ratio was higher in the elderly residing in care homes (23.3%, 95% CrI: 14.7 to 35.2%) than those residing in the community (7.9%, 95% CrI: 5.9 to 10.3%). On 2 December 2020, England was still far from herd immunity, with regional cumulative infection incidence between 7.6% (95% CrI: 5.4 to 10.2%) and 22.3% (95% CrI: 19.4 to 25.4%) of the population. Therefore, any vaccination campaign will need to achieve high coverage and a high degree of protection in vaccinated individuals to allow nonpharmaceutical interventions to be lifted without a resurgence of transmission., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution License 4.0 (CC BY).)

Published

2021

48. Reduction in mobility and COVID-19 transmission.

Author

Nouvellet P, Bhatia S, Cori A, Ainslie KEC, Baguelin M, Bhatt S, Boonyasiri A, Brazeau NF, Cattarino L, Cooper LV, Coupland H, Cucunuba ZM, Cuomo-Dannenburg G, Dighe A, Djaafara BA, Dorigatti I, Eales OD, van Elsland SL, Nascimento FF, FitzJohn RG, Gaythorpe KAM, Geidelberg L, Green WD, Hamlet A, Hauck K, Hinsley W, Imai N, Jeffrey B, Knock E, Laydon DJ, Lees JA, Mangal T, Mellan TA, Nedjati-Gilani G, Parag KV, Pons-Salort M, Ragonnet-Cronin M, Riley S, Unwin HJT, Verity R, Vollmer MAC, Volz E, Walker PGT, Walters CE, Wang H, Watson OJ, Whittaker C, Whittles LK, Xi X, Ferguson NM, and Donnelly CA

Subjects

Algorithms, COVID-19 epidemiology, COVID-19 virology, Communicable Disease Control statistics & numerical data, Global Health, Humans, Models, Theoretical, Physical Distancing, Quarantine methods, SARS-CoV-2 physiology, COVID-19 transmission, Communicable Disease Control methods, Pandemics prevention & control, SARS-CoV-2 isolation & purification

Abstract

In response to the COVID-19 pandemic, countries have sought to control SARS-CoV-2 transmission by restricting population movement through social distancing interventions, thus reducing the number of contacts. Mobility data represent an important proxy measure of social distancing, and here, we characterise the relationship between transmission and mobility for 52 countries around the world. Transmission significantly decreased with the initial reduction in mobility in 73% of the countries analysed, but we found evidence of decoupling of transmission and mobility following the relaxation of strict control measures for 80% of countries. For the majority of countries, mobility explained a substantial proportion of the variation in transmissibility (median adjusted R-squared: 48%, interquartile range - IQR - across countries [27-77%]). Where a change in the relationship occurred, predictive ability decreased after the relaxation; from a median adjusted R-squared of 74% (IQR across countries [49-91%]) pre-relaxation, to a median adjusted R-squared of 30% (IQR across countries [12-48%]) post-relaxation. In countries with a clear relationship between mobility and transmission both before and after strict control measures were relaxed, mobility was associated with lower transmission rates after control measures were relaxed indicating that the beneficial effects of ongoing social distancing behaviours were substantial.

Published

2021

49. Estimating the health impact of vaccination against ten pathogens in 98 low-income and middle-income countries from 2000 to 2030: a modelling study.

Author

Li X, Mukandavire C, Cucunubá ZM, Echeverria Londono S, Abbas K, Clapham HE, Jit M, Johnson HL, Papadopoulos T, Vynnycky E, Brisson M, Carter ED, Clark A, de Villiers MJ, Eilertson K, Ferrari MJ, Gamkrelidze I, Gaythorpe KAM, Grassly NC, Hallett TB, Hinsley W, Jackson ML, Jean K, Karachaliou A, Klepac P, Lessler J, Li X, Moore SM, Nayagam S, Nguyen DM, Razavi H, Razavi-Shearer D, Resch S, Sanderson C, Sweet S, Sy S, Tam Y, Tanvir H, Tran QM, Trotter CL, Truelove S, van Zandvoort K, Verguet S, Walker N, Winter A, Woodruff K, Ferguson NM, and Garske T

Subjects

Child, Preschool, Communicable Diseases economics, Cost-Benefit Analysis, Developing Countries, Female, Global Health, Humans, Immunization Programs, Male, Communicable Disease Control economics, Communicable Disease Control statistics & numerical data, Communicable Diseases mortality, Communicable Diseases virology, Models, Theoretical, Mortality trends, Quality-Adjusted Life Years, Vaccination economics, Vaccination statistics & numerical data

Abstract

Background: The past two decades have seen expansion of childhood vaccination programmes in low-income and middle-income countries (LMICs). We quantify the health impact of these programmes by estimating the deaths and disability-adjusted life-years (DALYs) averted by vaccination against ten pathogens in 98 LMICs between 2000 and 2030., Methods: 16 independent research groups provided model-based disease burden estimates under a range of vaccination coverage scenarios for ten pathogens: hepatitis B virus, Haemophilus influenzae type B, human papillomavirus, Japanese encephalitis, measles, Neisseria meningitidis serogroup A, Streptococcus pneumoniae, rotavirus, rubella, and yellow fever. Using standardised demographic data and vaccine coverage, the impact of vaccination programmes was determined by comparing model estimates from a no-vaccination counterfactual scenario with those from a reported and projected vaccination scenario. We present deaths and DALYs averted between 2000 and 2030 by calendar year and by annual birth cohort., Findings: We estimate that vaccination of the ten selected pathogens will have averted 69 million (95% credible interval 52-88) deaths between 2000 and 2030, of which 37 million (30-48) were averted between 2000 and 2019. From 2000 to 2019, this represents a 45% (36-58) reduction in deaths compared with the counterfactual scenario of no vaccination. Most of this impact is concentrated in a reduction in mortality among children younger than 5 years (57% reduction [52-66]), most notably from measles. Over the lifetime of birth cohorts born between 2000 and 2030, we predict that 120 million (93-150) deaths will be averted by vaccination, of which 58 million (39-76) are due to measles vaccination and 38 million (25-52) are due to hepatitis B vaccination. We estimate that increases in vaccine coverage and introductions of additional vaccines will result in a 72% (59-81) reduction in lifetime mortality in the 2019 birth cohort., Interpretation: Increases in vaccine coverage and the introduction of new vaccines into LMICs have had a major impact in reducing mortality. These public health gains are predicted to increase in coming decades if progress in increasing coverage is sustained., Funding: Gavi, the Vaccine Alliance and the Bill & Melinda Gates Foundation., (Copyright © 2021 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

2021

50. Database of epidemic trends and control measures during the first wave of COVID-19 in mainland China.

Author

Fu H, Wang H, Xi X, Boonyasiri A, Wang Y, Hinsley W, Fraser KJ, McCabe R, Olivera Mesa D, Skarp J, Ledda A, Dewé T, Dighe A, Winskill P, van Elsland SL, Ainslie KEC, Baguelin M, Bhatt S, Boyd O, Brazeau NF, Cattarino L, Charles G, Coupland H, Cucunuba ZM, Cuomo-Dannenburg G, Donnelly CA, Dorigatti I, Eales OD, FitzJohn RG, Flaxman S, Gaythorpe KAM, Ghani AC, Green WD, Hamlet A, Hauck K, Haw DJ, Jeffrey B, Laydon DJ, Lees JA, Mellan T, Mishra S, Nedjati-Gilani G, Nouvellet P, Okell L, Parag KV, Ragonnet-Cronin M, Riley S, Schmit N, Thompson HA, Unwin HJT, Verity R, Vollmer MAC, Volz E, Walker PGT, Walters CE, Watson OJ, Whittaker C, Whittles LK, Imai N, Bhatia S, and Ferguson NM

Subjects

COVID-19 prevention & control, China epidemiology, Contact Tracing, Databases, Factual, Humans, COVID-19 epidemiology, SARS-CoV-2

Abstract

Objectives: In this data collation study, we aimed to provide a comprehensive database describing the epidemic trends and responses during the first wave of coronavirus disease 2019 (COVID-19) throughout the main provinces in China., Methods: From mid-January to March 2020, we extracted publicly available data regarding the spread and control of COVID-19 from 31 provincial health authorities and major media outlets in mainland China. Based on these data, we conducted descriptive analyses of the epidemic in the six most-affected provinces., Results: School closures, travel restrictions, community-level lockdown, and contact tracing were introduced concurrently around late January but subsequent epidemic trends differed among provinces. Compared with Hubei, the other five most-affected provinces reported a lower crude case fatality ratio and proportion of critical and severe hospitalised cases. From March 2020, as the local transmission of COVID-19 declined, switching the focus of measures to the testing and quarantine of inbound travellers may have helped to sustain the control of the epidemic., Conclusions: Aggregated indicators of case notifications and severity distributions are essential for monitoring an epidemic. A publicly available database containing these indicators and information regarding control measures is a useful resource for further research and policy planning in response to the COVID-19 epidemic., (Copyright © 2020 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2021