Your search keyword '"Leclerc, Quentin J."' showing total 47 results

1. Using contact network dynamics to implement efficient interventions against pathogen spread in hospital settings: A modelling study

Author

Leclerc, Quentin J., Duval, Audrey, Guillemot, Didier, Opatowski, Lulla, and Temime, Laura

Subjects

International Business Machines Corp., Vaccination -- Health aspects -- Analysis, Staphylococcus aureus -- Analysis -- Health aspects, Infection -- Health aspects -- Analysis, Methicillin -- Health aspects -- Analysis, Disease transmission -- Analysis -- Health aspects, Epidemiology -- Analysis -- Health aspects, Computer industry -- Analysis -- Health aspects, Persistent vegetative state -- Analysis -- Health aspects, Nurses -- Analysis -- Health aspects, Microcomputer industry, Computer industry, Biological sciences

Abstract

Background Long-term care facilities (LTCFs) are hotspots for pathogen transmission. Infection control interventions are essential, but the high density and heterogeneity of interindividual contacts within LTCF may hinder their efficacy. Here, we explore how the patient-staff contact structure may inform effective intervention implementation. Methods and findings Using an individual-based model (IBM), we reproduced methicillin-resistant Staphylococcus aureus colonisation transmission dynamics over a detailed contact network recorded within a French LTCF of 327 patients and 263 staff over 3 months. Simulated baseline cumulative colonisation incidence was 21 patients (prediction interval: 11, 31) and 35 staff (prediction interval: 19, 54). We examined the potential impact of 3 types of interventions against transmission (reallocation reducing the number of unique contacts per staff, reinforced contact precautions, and hypothetical vaccination protecting against acquisition), targeted towards specific populations. All 3 interventions were effective when applied to all nurses or healthcare assistants (median reduction in MRSA colonisation incidence up to 35%), but the benefit did not exceed 8% when targeting any other single staff category. We identified 'supercontactor' individuals with most contacts ('frequency-based,' overrepresented among nurses, porters, and rehabilitation staff) or with the longest cumulative time spent in contact ('duration-based,' overrepresented among healthcare assistants and patients in elderly care or persistent vegetative state (PVS)). Targeting supercontactors enhanced interventions against pathogen spread in the LTCF. With contact precautions, targeting frequency-based staff supercontactors led to the highest incidence reduction (20%, 95% CI: 19, 21). Vaccinating a mix of frequency- and duration-based staff supercontactors led to a higher reduction (23%, 95% CI: 22, 24) than all other approaches. Although based on data from a single LTCF, when varying epidemiological parameters to extend to other pathogens, our results suggest that targeting supercontactors is always the most effective strategy, indicating this approach could be applied to prevent transmission of other nosocomial pathogens. Conclusions By characterising the contact structure in hospital settings and identifying the categories of staff and patients more likely to be supercontactors, with either more or longer contacts than others, interventions against nosocomial spread could be more effective. We find that the most efficient implementation strategy depends on the intervention (reallocation, contact precautions, vaccination) and target population (staff, patients, supercontactors). Importantly, both staff and patients may be supercontactors, highlighting the importance of including patients in measures to prevent pathogen transmission in LTCF., Author(s): Quentin J. Leclerc 1,2,3,*, Audrey Duval 1,2,3, Didier Guillemot 1,2,4, Lulla Opatowski 1,2, Laura Temime 3,5 Introduction Healthcare-associated infections (HAIs) are a major threat worldwide, with more than 4 [...]

Published

2024

2. Longitudinal social contact data analysis: insights from 2 years of data collection in Belgium during the COVID-19 pandemic

Author

Loedy, Neilshan, Coletti, Pietro, Wambua, James, Hermans, Lisa, Willem, Lander, Jarvis, Christopher I., Wong, Kerry L. M., Edmunds, W. John, Robert, Alexis, Leclerc, Quentin J., Gimma, Amy, Molenberghs, Geert, Beutels, Philippe, Faes, Christel, and Hens, Niel

Published

2023

3. Investigating the feasibility and potential of combining industry AMR monitoring systems: a comparison with WHO GLASS

Author

Rahbé, Eve, primary, Kovacevic, Aleksandra, additional, Opatowski, Lulla, additional, and Leclerc, Quentin J., additional

Published

2024

4. An algorithm to build synthetic temporal contact networks based on close-proximity interactions data.

Author

Duval, Audrey, Leclerc, Quentin J., Guillemot, Didier, Temime, Laura, and Opatowski, Lulla

Subjects

*TIME-varying networks, *INFECTIOUS disease transmission, *RANDOM graphs, *DATA augmentation, *ALGORITHMS, *LONG-term care facilities

Abstract

Small populations (e.g., hospitals, schools or workplaces) are characterised by high contact heterogeneity and stochasticity affecting pathogen transmission dynamics. Empirical individual contact data provide unprecedented information to characterize such heterogeneity and are increasingly available, but are usually collected over a limited period, and can suffer from observation bias. We propose an algorithm to stochastically reconstruct realistic temporal networks from individual contact data in healthcare settings (HCS) and test this approach using real data previously collected in a long-term care facility (LTCF). Our algorithm generates full networks from recorded close-proximity interactions, using hourly inter-individual contact rates and information on individuals' wards, the categories of staff involved in contacts, and the frequency of recurring contacts. It also provides data augmentation by reconstructing contacts for days when some individuals are present in the HCS without having contacts recorded in the empirical data. Recording bias is formalized through an observation model, to allow direct comparison between the augmented and observed networks. We validate our algorithm using data collected during the i-Bird study, and compare the empirical and reconstructed networks. The algorithm was substantially more accurate to reproduce network characteristics than random graphs. The reconstructed networks reproduced well the assortativity by ward (first–third quartiles observed: 0.54–0.64; synthetic: 0.52–0.64) and the hourly staff and patient contact patterns. Importantly, the observed temporal correlation was also well reproduced (0.39–0.50 vs 0.37–0.44), indicating that our algorithm could recreate a realistic temporal structure. The algorithm consistently recreated unobserved contacts to generate full reconstructed networks for the LTCF. To conclude, we propose an approach to generate realistic temporal contact networks and reconstruct unobserved contacts from summary statistics computed using individual-level interaction networks. This could be applied and extended to generate contact networks to other HCS using limited empirical data, to subsequently inform individual-based epidemic models. Author summary: Contact networks are the most informative representation of the contact heterogeneity, and therefore infectious disease transmission risk, in small populations. However, the data collection required is costly and complex, usually limited to a few days only and likely to suffer from partially observed data, making the practical integration of networks into models challenging. In this article, we present an approach leveraging empirical individual contact data to stochastically reconstruct realistic temporal networks in healthcare settings. The algorithm accounts for population specificities including the hourly distribution of contact rates between different individuals (staff categories, patients) and the probability for contact repetition between the same individuals. We illustrate and validate this algorithm using a real contact network measured in a long-term care facility. Our approach outperforms random graphs informed by the same data to accurately reproduce observed network characteristics and hourly staff-patient contact patterns. The algorithm recreates unobserved contacts, providing data augmentation for times with missing information. This method should improve the usability and reliability of contact networks, and therefore promote integration of empirical contact data in individual-based models. [ABSTRACT FROM AUTHOR]

Published

2024

5. Routine childhood immunisation during the COVID-19 pandemic in Africa: a benefit–risk analysis of health benefits versus excess risk of SARS-CoV-2 infection

Author

Houben, Rein M G J, Edmunds, W John, Villabona-Arenas, Christian Julian, Atkins, Katherine E, Knight, Gwenan M, Sun, Fiona Yueqian, Auzenbergs, Megan, Rosello, Alicia, Klepac, Petra, Hellewell, Joel, Russell, Timothy W, Tully, Damien C, Emery, Jon C, Gibbs, Hamish P, Munday, James D, Quilty, Billy J, Diamond, Charlie, Pearson, Carl A B, Leclerc, Quentin J, Nightingale, Emily S, Liu, Yang, Endo, Akira, Deol, Arminder K, Kucharski, Adam J, Abbott, Sam, Jarvis, Christopher I, O'Reilly, Kathleen, Jombart, Thibaut, Gimma, Amy, Bosse, Nikos I, Prem, Kiesha, Hué, Stéphane, Davies, Nicholas G, Eggo, Rosalind M, Clifford, Samuel, Medley, Graham, Abbas, Kaja, Procter, Simon R, van Zandvoort, Kevin, Clark, Andrew, Funk, Sebastian, Mengistu, Tewodaj, Hogan, Dan, Dansereau, Emily, Jit, Mark, and Flasche, Stefan

Published

2020

6. Effectiveness of isolation, testing, contact tracing, and physical distancing on reducing transmission of SARS-CoV-2 in different settings: a mathematical modelling study

Author

Emery, Jon C, Medley, Graham, Munday, James D, Russell, Timothy W, Leclerc, Quentin J, Diamond, Charlie, Procter, Simon R, Gimma, Amy, Sun, Fiona Yueqian, Gibbs, Hamish P, Rosello, Alicia, van Zandvoort, Kevin, Hué, Stéphane, Meakin, Sophie R, Deol, Arminder K, Knight, Gwen, Jombart, Thibaut, Foss, Anna M, Bosse, Nikos I, Atkins, Katherine E, Quilty, Billy J, Lowe, Rachel, Prem, Kiesha, Flasche, Stefan, Pearson, Carl A B, Houben, Rein M G J, Nightingale, Emily S, Endo, Akira, Tully, Damien C, Liu, Yang, Villabona-Arenas, Julian, O'Reilly, Kathleen, Funk, Sebastian, Eggo, Rosalind M, Jit, Mark, Rees, Eleanor M, Hellewell, Joel, Clifford, Samuel, Jarvis, Christopher I, Abbott, Sam, Auzenbergs, Megan, Davies, Nicholas G, Simons, David, Kucharski, Adam J, Klepac, Petra, Conlan, Andrew J K, Kissler, Stephen M, Tang, Maria L, Fry, Hannah, Gog, Julia R, and Edmunds, W John

Published

2020

7. Global, regional, and national estimates of the population at increased risk of severe COVID-19 due to underlying health conditions in 2020: a modelling study

Author

Nightingale, Emily S, O'Reilly, Kathleen, Jombart, Thibaut, Edmunds, W John, Rosello, Alicia, Sun, Fiona Yueqian, Atkins, Katherine E, Bosse, Nikos I, Clifford, Samuel, Russell, Timothy W, Deol, Arminder K, Liu, Yang, Procter, Simon R, Leclerc, Quentin J, Medley, Graham, Knight, Gwen, Munday, James D, Kucharski, Adam J, Pearson, Carl A B, Klepac, Petra, Prem, Kiesha, Houben, Rein M G J, Endo, Akira, Flasche, Stefan, Davies, Nicholas G, Diamond, Charlie, van Zandvoort, Kevin, Funk, Sebastian, Auzenbergs, Megan, Rees, Eleanor M, Tully, Damien C, Emery, Jon C, Quilty, Billy J, Abbott, Sam, Villabona-Arenas, Ch Julian, Hué, Stéphane, Hellewell, Joel, Gimma, Amy, Jarvis, Christopher I, Clark, Andrew, Jit, Mark, Warren-Gash, Charlotte, Guthrie, Bruce, Wang, Harry H X, Mercer, Stewart W, Sanderson, Colin, McKee, Martin, Troeger, Christopher, Ong, Kanyin L, Checchi, Francesco, Perel, Pablo, Joseph, Sarah, Gibbs, Hamish P, Banerjee, Amitava, and Eggo, Rosalind M

Published

2020

8. Comparing the Analysis and Results of a Modified Social Accounting Matrix Framework with Conventional Methods of Reporting Indirect Non-Medical Costs

Author

Standaert, Baudouin, Sauboin, Christophe, Leclerc, Quentin J., and Connolly, Mark P.

Published

2021

9. Using contact network dynamics to implement efficient interventions against pathogen spread in hospital settings

Author

Leclerc, Quentin J, primary, Duval, Audrey, additional, Guillemot, Didier, additional, Opatowski, Lulla, additional, and Temime, Laura, additional

Published

2023

10. An algorithm to build synthetic temporal contact networks based on close-proximity interactions data

Author

Duval, Audrey, primary, Leclerc, Quentin J, additional, Guillemot, Didier, additional, Temime, Laura, additional, and Opatowski, Lulla, additional

Published

2023

11. Correction for Leclerc et al., “Growth-Dependent Predation and Generalized Transduction of Antimicrobial Resistance by Bacteriophage”

Author

Leclerc, Quentin J., primary, Wildfire, Jacob, additional, Gupta, Arya, additional, Lindsay, Jodi A., additional, and Knight, Gwenan M., additional

Published

2023

12. Longitudinal social contact data analysis: insights from 2 years of data collection in Belgium during the COVID-19 pandemic

Author

Loedy, Neilshan, primary, Coletti, Pietro, additional, Wambua, James, additional, Hermans, Lisa, additional, Willem, Lander, additional, Jarvis, Christopher I., additional, Wong, Kerry L.M., additional, Edmunds, W. John, additional, Robert, Alexis, additional, Leclerc, Quentin J., additional, Gimma, Amy, additional, Molenberghs, Geert, additional, Beutels, Philippe, additional, Faes, Christel, additional, and Hens, Niel, additional

Published

2023

13. Modelling the synergistic effect of bacteriophage and antibiotics on bacteria: Killers and drivers of resistance evolution

Author

Leclerc, Quentin J., primary, Lindsay, Jodi A., additional, and Knight, Gwenan M., additional

Published

2022

14. Growth-Dependent Predation and Generalized Transduction of Antimicrobial Resistance by Bacteriophage

Author

Leclerc, Quentin J., primary, Wildfire, Jacob, additional, Gupta, Arya, additional, Lindsay, Jodi A., additional, and Knight, Gwenan M., additional

Published

2022

15. Real-time monitoring of COVID-19 dynamics using automated trend fitting and anomaly detection

Author

Jombart, Thibaut, Ghozzi, Stéphane, Schumacher, Dirk, Taylor, Timothy J, Leclerc, Quentin J, Jit, Mark, Flasche, Stefan, Greaves, Felix, Ward, Tom, Eggo, Rosalind M, Nightingale, Emily, Meakin, Sophie, Brady, Oliver J, Centre for Mathematical Modelling of Infectious Diseases COVID-1, Medley, Graham F, Höhle, Michael, Edmunds, W John, and Centre for Mathematical Modelling

Abstract

As several countries gradually release social distancing measures, rapid detection of new localized COVID-19 hotspots and subsequent intervention will be key to avoiding large-scale resurgence of transmission. We introduce ASMODEE (automatic selection of models and outlier detection for epidemics), a new tool for detecting sudden changes in COVID-19 incidence. Our approach relies on automatically selecting the best (fitting or predicting) model from a range of user-defined time series models, excluding the most recent data points, to characterize the main trend in an incidence. We then derive prediction intervals and classify data points outside this interval as outliers, which provides an objective criterion for identifying departures from previous trends. We also provide a method for selecting the optimal breakpoints, used to define how many recent data points are to be excluded from the trend fitting procedure. The analysis of simulated COVID-19 outbreaks suggests ASMODEE compares favourably with a state-of-art outbreak-detection algorithm while being simpler and more flexible. As such, our method could be of wider use for infectious disease surveillance. We illustrate ASMODEE using publicly available data of National Health Service (NHS) Pathways reporting potential COVID-19 cases in England at a fine spatial scale, showing that the method would have enabled the early detection of the flare-ups in Leicester and Blackburn with Darwen, two to three weeks before their respective lockdown. ASMODEE is implemented in the free R package trendbreaker. This article is part of the theme issue 'Modelling that shaped the early COVID-19 pandemic response in the UK'.

Published

2021

16. Importance of patient bed pathways and length of stay differences in predicting COVID-19 hospital bed occupancy in England

Author

Leclerc, Quentin J, Fuller, Naomi M, Keogh, Ruth H, Diaz-Ordaz, Karla, Sekula, Richard, Semple, Malcolm G, ISARIC4C Investigators, CMMID COVID-19 Working Group, Atkins, Katherine E, Procter, Simon R, and Knight, Gwenan M

Abstract

BACKGROUND: Predicting bed occupancy for hospitalised patients with COVID-19 requires understanding of length of stay (LoS) in particular bed types. LoS can vary depending on the patient's "bed pathway" - the sequence of transfers of individual patients between bed types during a hospital stay. In this study, we characterise these pathways, and their impact on predicted hospital bed occupancy. METHODS: We obtained data from University College Hospital (UCH) and the ISARIC4C COVID-19 Clinical Information Network (CO-CIN) on hospitalised patients with COVID-19 who required care in general ward or critical care (CC) beds to determine possible bed pathways and LoS. We developed a discrete-time model to examine the implications of using either bed pathways or only average LoS by bed type to forecast bed occupancy. We compared model-predicted bed occupancy to publicly available bed occupancy data on COVID-19 in England between March and August 2020. RESULTS: In both the UCH and CO-CIN datasets, 82% of hospitalised patients with COVID-19 only received care in general ward beds. We identified four other bed pathways, present in both datasets: "Ward, CC, Ward", "Ward, CC", "CC" and "CC, Ward". Mean LoS varied by bed type, pathway, and dataset, between 1.78 and 13.53 days. For UCH, we found that using bed pathways improved the accuracy of bed occupancy predictions, while only using an average LoS for each bed type underestimated true bed occupancy. However, using the CO-CIN LoS dataset we were not able to replicate past data on bed occupancy in England, suggesting regional LoS heterogeneities. CONCLUSIONS: We identified five bed pathways, with substantial variation in LoS by bed type, pathway, and geography. This might be caused by local differences in patient characteristics, clinical care strategies, or resource availability, and suggests that national LoS averages may not be appropriate for local forecasts of bed occupancy for COVID-19. TRIAL REGISTRATION: The ISARIC WHO CCP-UK study ISRCTN66726260 was retrospectively registered on 21/04/2020 and designated an Urgent Public Health Research Study by NIHR.

Published

2021

17. Implications of the school-household network structure on SARS-CoV-2 transmission under school reopening strategies in England

Author

Munday, James D., Sherratt, Katharine, Meakin, Sophie, Endo, Akira, Pearson, Carl A. B., Hellewell, Joel, Abbott, Sam, Bosse, Nikos I., Eggo, Rosalind M., Simons, David, O’Reilly, Kathleen, Russell, Timothy W., Lowe, Rachel, Leclerc, Quentin J., Emery, Jon C., Klepac, Petra, Nightingale, Emily S., Quaife, Matthew, van Zandvoort, Kevin, Knight, Gwenan M., Jombart, Thibaut, Villabona-Arenas, C. Julian, Rees, Eleanor M., Diamond, Charlie, Auzenbergs, Megan, Medley, Graham, Foss, Anna M., Gore-Langton, Georgia R., Deol, Arminder K., Jit, Mark, Gibbs, Hamish P., Procter, Simon R., Rosello, Alicia, Jarvis, Christopher I., Liu, Yang, Houben, Rein M. G. J., Hué, Stéphane, Clifford, Samuel, Quilty, Billy J., Gimma, Amy, Tully, Damien C., Sun, Fiona Yueqian, Prem, Kiesha, Atkins, Katherine E., Wallinga, Jacco, Edmunds, W. John, van Hoek, Albert Jan, and Funk, Sebastian

Subjects

0301 basic medicine, Economic growth, 2019-20 coronavirus outbreak, Coronavirus disease 2019 (COVID-19), Adolescent, genetic structures, Epidemiology, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Science, education, General Physics and Astronomy, Network structure, Risk Assessment, General Biochemistry, Genetics and Molecular Biology, Article, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Risk Factors, Pandemic, Disease Transmission, Infectious, Humans, Computational models, 030212 general & internal medicine, Disease Transmission, Infectious/prevention & control, England/epidemiology, Child, Pandemics, COVID-19/epidemiology, Family Characteristics, Multidisciplinary, Schools, SARS-CoV-2, SARS-CoV-2/isolation & purification, COVID-19, General Chemistry, Schools/organization & administration, 030104 developmental biology, Transmission (mechanics), England, Viral infection, Child, Preschool, Business, Risk assessment, Disease transmission

Abstract

In early 2020 many countries closed schools to mitigate the spread of SARS-CoV-2. Since then, governments have sought to relax the closures, engendering a need to understand associated risks. Using address records, we construct a network of schools in England connected through pupils who share households. We evaluate the risk of transmission between schools under different reopening scenarios. We show that whilst reopening select year-groups causes low risk of large-scale transmission, reopening secondary schools could result in outbreaks affecting up to 2.5 million households if unmitigated, highlighting the importance of careful monitoring and within-school infection control to avoid further school closures or other restrictions., Many countries have closed schools as part of their COVID-19 response. Here, the authors model SARS-CoV-2 transmission on a network of schools and households in England, and find that risk of transmission between schools is lower if primary schools are open than if secondary schools are open.

Published

2021

18. Analysis of temporal trends in potential COVID-19 cases reported through NHS Pathways England

Author

Leclerc, Quentin J, Nightingale, Emily S, Abbott, Sam, CMMID COVID-19 Working Group, and Jombart, Thibaut

Abstract

The National Health Service (NHS) Pathways triage system collates data on enquiries to 111 and 999 services in England. Since the 18th of March 2020, these data have been made publically available for potential COVID-19 symptoms self-reported by members of the public. Trends in such reports over time are likely to reflect behaviour of the ongoing epidemic within the wider community, potentially capturing valuable information across a broader severity profile of cases than hospital admission data. We present a fully reproducible analysis of temporal trends in NHS Pathways reports until 14th May 2020, nationally and regionally, and demonstrate that rates of growth/decline and effective reproduction number estimated from these data may be useful in monitoring transmission. This is a particularly pressing issue as lockdown restrictions begin to be lifted and evidence of disease resurgence must be constantly reassessed. We further assess the correlation between NHS Pathways reports and a publicly available NHS dataset of COVID-19-associated deaths in England, finding that enquiries to 111/999 were strongly associated with daily deaths reported 16 days later. Our results highlight the potential of NHS Pathways as the basis of an early warning system. However, this dataset relies on self-reported symptoms, which are at risk of being severely biased. Further detailed work is therefore necessary to investigate potential behavioural issues which might otherwise explain our conclusions.

Published

2021

19. The dual nature of bacteriophage: growth-dependent predation and generalised transduction of antimicrobial resistance

Author

Leclerc, Quentin J, primary, Wildfire, Jacob, additional, Gupta, Arya, additional, Lindsay, Jodi A, additional, and Knight, Gwenan M, additional

Published

2021

20. Additional file 1 of Importance of patient bed pathways and length of stay differences in predicting COVID-19 hospital bed occupancy in England

Author

Leclerc, Quentin J., Fuller, Naomi M., Keogh, Ruth H., Diaz-Ordaz, Karla, Sekula, Richard, Semple, Malcolm G., Atkins, Katherine E., Procter, Simon R., and Knight, Gwenan M.

Subjects

Data_FILES

Abstract

Additional file 1.

Published

2021

21. Strategies to reduce the risk of SARS-CoV-2 importation from international travellers: modelling estimations for the United Kingdom, July 2020

Author

Clifford, Samuel, Quilty, Billy J, Russell, Timothy W, Liu, Yang, Chan, Yung-Wai D, Pearson, Carl A B, Eggo, Rosalind M, Endo, Akira, Flasche, Stefan, Edmunds, W John, Sherratt, Katharine, Hué, Stéphane, Quaife, Matthew, Bosse, Nikos I, Medley, Graham, Auzenbergs, Megan, Kucharski, Adam J, Davies, Nicholas G, Brady, Oliver, Meakin, Sophie R, Houben, Rein M G J, Atkins, Katherine E, Prem, Kiesha, Villabona-Arenas, C Julian, Gibbs, Hamish P, Jombart, Thibaut, Diamond, Charlie, Klepac, Petra, Deol, Arminder K, Lowe, Rachel, Rudge, James W, Jit, Mark, Funk, Sebastian, Knight, Gwenan M., Procter, Simon R., Simons, David, Leclerc, Quentin J, Munday, James D, Gimma, Amy, Gore-Langton, Georgia R, Jarvis, Christopher I, Emery, Jon C, Foss, Anna M, O'Reilly, Kathleen, Hellewell, Joel, Nightingale, Emily S, van Zandvoort, Kevin, Tully, Damien C, Abbott, Sam, Abbas, Kaja, Sun, Fiona Yueqian, and Rosello, Alicia

Subjects

COVID-19 Vaccines, Coronavirus disease 2019 (COVID-19), Epidemiology, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), law.invention, Pcr test, law, Virology, Environmental health, Quarantine, Pandemic, media_common.cataloged_instance, Medicine, Humans, European union, Pandemics, media_common, business.industry, SARS-CoV-2, Incidence (epidemiology), Research, Public Health, Environmental and Occupational Health, COVID-19, PCR testing, United Kingdom, Transmission (mechanics), business, travel screening

Abstract

Background To mitigate SARS-CoV-2 transmission risks from international air travellers, many countries implemented a combination of up to 14 days of self-quarantine upon arrival plus PCR testing in the early stages of the COVID-19 pandemic in 2020. Aim To assess the effectiveness of quarantine and testing of international travellers to reduce risk of onward SARS-CoV-2 transmission into a destination country in the pre-COVID-19 vaccination era. Methods We used a simulation model of air travellers arriving in the United Kingdom from the European Union or the United States, incorporating timing of infection stages while varying quarantine duration and timing and number of PCR tests. Results Quarantine upon arrival with a PCR test on day 7 plus a 1-day delay for results can reduce the number of infectious arriving travellers released into the community by a median 94% (95% uncertainty interval (UI): 89–98) compared with a no quarantine/no test scenario. This reduction is similar to that achieved by a 14-day quarantine period (median > 99%; 95% UI: 98–100). Even shorter quarantine periods can prevent a substantial amount of transmission; all strategies in which travellers spend at least 5 days (mean incubation period) in quarantine and have at least one negative test before release are highly effective (median reduction 89%; 95% UI: 83–95)). Conclusion The effect of different screening strategies impacts asymptomatic and symptomatic individuals differently. The choice of an optimal quarantine and testing strategy for unvaccinated air travellers may vary based on the number of possible imported infections relative to domestic incidence.

Published

2021

22. Modelling the medium-term dynamics of SARS-CoV-2 transmission in England in the Omicron era.

Author

Barnard, Rosanna C., Davies, Nicholas G., Centre for Mathematical Modelling of Infectious Diseases COVID-19 working group, Munday, James D., Lowe, Rachel, Knight, Gwenan M., Leclerc, Quentin J., Tully, Damien C., Hodgson, David, Pung, Rachael, Hellewell, Joel, Koltai, Mihaly, Simons, David, Abbas, Kaja, Kucharski, Adam J., Procter, Simon R., Sandmann, Frank G., Pearson, Carl A. B., Prem, Kiesha, and Showering, Alicia

Subjects

SARS-CoV-2 Omicron variant, INFECTIOUS disease transmission, BOOSTER vaccines, SARS-CoV-2, VACCINE effectiveness

Abstract

England has experienced a heavy burden of COVID-19, with multiple waves of SARS-CoV-2 transmission since early 2020 and high infection levels following the emergence and spread of Omicron variants since late 2021. In response to rising Omicron cases, booster vaccinations were accelerated and offered to all adults in England. Using a model fitted to more than 2 years of epidemiological data, we project potential dynamics of SARS-CoV-2 infections, hospital admissions and deaths in England to December 2022. We consider key uncertainties including future behavioural change and waning immunity and assess the effectiveness of booster vaccinations in mitigating SARS-CoV-2 disease burden between October 2021 and December 2022. If no new variants emerge, SARS-CoV-2 transmission is expected to decline, with low levels remaining in the coming months. The extent to which projected SARS-CoV-2 transmission resurges later in 2022 depends largely on assumptions around waning immunity and to some extent, behaviour, and seasonality. This mathematical modelling study projects the dynamics of SARS-CoV-2 in England until the end of 2022 assuming that the Omicron BA.2 sublineage remains dominant. They show that booster vaccination was highly effective in mitigating severe outcomes and that future dynamics will depend greatly on assumptions about waning immunity. [ABSTRACT FROM AUTHOR]

Published

2022

23. Changing travel patterns in China during the early stages of the COVID-19 pandemic

Author

Gibbs, Hamish, Liu, Yang, Pearson, Carl A. B., Jarvis, Christopher I., Grundy, Chris, Quilty, Billy J., Diamond, Charlie, Simons, David, Gimma, Amy, Leclerc, Quentin J., Auzenbergs, Megan, Lowe, Rachel, O’Reilly, Kathleen, Quaife, Matthew, Hellewell, Joel, Knight, Gwenan M., Jombart, Thibaut, Klepac, Petra, Procter, Simon R., Deol, Arminder K., Rees, Eleanor M., Flasche, Stefan, Kucharski, Adam J., Abbott, Sam, Sun, Fiona Yueqian, Endo, Akira, Medley, Graham, Munday, James D., Meakin, Sophie R., Bosse, Nikos I., Edmunds, W. John, Davies, Nicholas G., Prem, Kiesha, Hué, Stéphane, Villabona-Arenas, C. Julian, Nightingale, Emily S., Houben, Rein M. G. J., Foss, Anna M., Tully, Damien C., Emery, Jon C., van Zandvoort, Kevin, Atkins, Katherine E., Rosello, Alicia, Funk, Sebastian, Jit, Mark, Clifford, Samuel, Russell, Timothy W., and Eggo, Rosalind M.

Subjects

0301 basic medicine, Time Factors, Epidemiology, General Physics and Astronomy, Transportation, 0302 clinical medicine, Health care, Pandemic, Computational models, 030212 general & internal medicine, lcsh:Science, Holidays, Travel, 0303 health sciences, Multidisciplinary, Geography, Public Health, Coronavirus Infections, Mainland China, China, 2019-20 coronavirus outbreak, medicine.medical_specialty, Coronavirus disease 2019 (COVID-19), Science, Pneumonia, Viral, Policy and public health in microbiology, Article, General Biochemistry, Genetics and Molecular Biology, Betacoronavirus, 03 medical and health sciences, Development economics, medicine, Humans, Pandemics, 030304 developmental biology, Population Density, SARS-CoV-2, business.industry, Public health, COVID-19, General Chemistry, 030104 developmental biology, 13. Climate action, lcsh:Q, Demographic economics, business, Delivery of Health Care, human activities

Abstract

Understanding changes in human mobility in the early stages of the COVID-19 pandemic is crucial for assessing the impacts of travel restrictions designed to reduce disease spread. Here, relying on data from mainland China, we investigate the spatio-temporal characteristics of human mobility between 1st January and 1st March 2020, and discuss their public health implications. An outbound travel surge from Wuhan before travel restrictions were implemented was also observed across China due to the Lunar New Year, indicating that holiday travel may have played a larger role in mobility changes compared to impending travel restrictions. Holiday travel also shifted healthcare pressure related to COVID-19 towards locations with lower healthcare capacity. Network analyses showed no sign of major changes in the transportation network after Lunar New Year. Changes observed were temporary and did not lead to structural reorganisation of the transportation network during the study period., COVID-19-related travel restrictions were imposed in China around the same time as major annual holiday migrations, with unknown combined impacts on mobility patterns. Here, the authors show that restructuring of the travel network in response to restrictions was temporary, whilst holiday-related travel increased pressure on healthcare services with lower capacity.

Published

2020

24. Using a real-world network to model localized COVID-19 control strategies

Author

Firth, Josh A., Hellewell, Joel, Klepac, Petra, Kissler, Stephen, Jit, Mark, Atkins, Katherine E., Clifford, Samuel, Villabona-Arenas, C. Julian, Meakin, Sophie R., Diamond, Charlie, Bosse, Nikos I., Munday, James D., Prem, Kiesha, Foss, Anna M., Nightingale, Emily S., Zandvoort, Kevin van, Davies, Nicholas G., Gibbs, Hamish P., Medley, Graham, Gimma, Amy, Flasche, Stefan, Simons, David, Auzenbergs, Megan, Russell, Timothy W., Quilty, Billy J., Rees, Eleanor M., Leclerc, Quentin J., Edmunds, W. John, Funk, Sebastian, Houben, Rein M. G. J., Knight, Gwenan M., Abbott, Sam, Sun, Fiona Yueqian, Lowe, Rachel, Tully, Damien C., Procter, Simon R., Jarvis, Christopher I., Endo, Akira, O’Reilly, Kathleen, Emery, Jon C., Jombart, Thibaut, Rosello, Alicia, Deol, Arminder K., Quaife, Matthew, Hué, Stéphane, Liu, Yang, Eggo, Rosalind M., Pearson, Carl A. B., Kucharski, Adam J., and Spurgin, Lewis G.

Subjects

0301 basic medicine, Social network, Coronavirus disease 2019 (COVID-19), business.industry, Computer science, Distancing, Control (management), General Medicine, Tracing, Computer security, computer.software_genre, General Biochemistry, Genetics and Molecular Biology, law.invention, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Transmission (mechanics), law, 030220 oncology & carcinogenesis, Isolation (database systems), business, computer, Contact tracing

Abstract

Case isolation and contact tracing can contribute to the control of COVID-19 outbreaks1,2. However, it remains unclear how real-world social networks could influence the effectiveness and efficiency of such approaches. To address this issue, we simulated control strategies for SARS-CoV-2 transmission in a real-world social network generated from high-resolution GPS data that were gathered in the course of a citizen-science experiment3,4. We found that tracing the contacts of contacts reduced the size of simulated outbreaks more than tracing of only contacts, but this strategy also resulted in almost half of the local population being quarantined at a single point in time. Testing and releasing non-infectious individuals from quarantine led to increases in outbreak size, suggesting that contact tracing and quarantine might be most effective as a 'local lockdown' strategy when contact rates are high. Finally, we estimated that combining physical distancing with contact tracing could enable epidemic control while reducing the number of quarantined individuals. Our findings suggest that targeted tracing and quarantine strategies would be most efficient when combined with other control measures such as physical distancing.

Published

2020

25. The importance of supplementary immunisation activities to prevent measles outbreaks during the COVID-19 pandemic in Kenya

Author

Mburu, C. N., Ojal, J., Chebet, R., Akech, D., Karia, B., Tuju, J., Sigilai, A., Abbas, K., Jit, M., Funk, S., Smits, G., van Gageldonk, P. G. M., van der Klis, F. R. M., Tabu, C., Nokes, D. J., Munday, James D., Pearson, Carl A. B., Procter, Simon R., Brady, Oliver, Simons, David, Lowe, Rachel, Edmunds, W. John, Sherratt, Katharine, Barnard, Rosanna C., Rosello, Alicia, Kucharski, Adam J., Sun, Fiona Yueqian, Bosse, Nikos I., Klepac, Petra, Liu, Yang, Prem, Kiesha, Knight, Gwenan M., Endo, Akira, Abbott, Sam, Nightingale, Emily S., Jombart, Thibaut, Emery, Jon C., Gore-Langton, Georgia R., Hellewell, Joel, Rudge, James W., Gibbs, Hamish P., O’Reilly, Kathleen, van Zandvoort, Kevin, Chan, Yung-Wai Desmond, Tully, Damien C., Foss, Anna M., Jarvis, Christopher I., Atkins, Katherine E., Clifford, Samuel, Quaife, Matthew, Quilty, Billy J., Houben, Rein M. G. J., Eggo, Rosalind M., Medley, Graham, Meakin, Sophie R., Russell, Timothy W., Davies, Nicholas G., Diamond, Charlie, Deol, Arminder K., Villabona-Arenas, C. Julian, Hué, Stéphane, Auzenbergs, Megan, Leclerc, Quentin J., Gimma, Amy, Scott, JAG, Flasche, S., Adetifa, IMO, LSHTM CMMID COVID-19 Working Group, and Group, LSHTM CMMID COVID-19 Working

Subjects

Male, COVID-19, Supplementary immunisation activities, Vaccination coverage, Outbreak, Measles, medicine.medical_specialty, Adolescent, Coronavirus disease 2019 (COVID-19), RJ, Measles Vaccine, 030231 tropical medicine, lcsh:Medicine, Measles outbreak, Disease Outbreaks, Herd immunity, 03 medical and health sciences, 0302 clinical medicine, Environmental health, Epidemiology, Pandemic, medicine, Humans, 030212 general & internal medicine, Child, Immunization Programs, SARS-CoV-2, business.industry, lcsh:R, Infant, Newborn, Infant, General Medicine, medicine.disease, Kenya, Increased risk, Child, Preschool, Female, business, RA, Research Article

Abstract

Background The COVID-19 pandemic has disrupted routine measles immunisation and supplementary immunisation activities (SIAs) in most countries including Kenya. We assessed the risk of measles outbreaks during the pandemic in Kenya as a case study for the African Region. Methods Combining measles serological data, local contact patterns, and vaccination coverage into a cohort model, we predicted the age-adjusted population immunity in Kenya and estimated the probability of outbreaks when contact-reducing COVID-19 interventions are lifted. We considered various scenarios for reduced measles vaccination coverage from April 2020. Results In February 2020, when a scheduled SIA was postponed, population immunity was close to the herd immunity threshold and the probability of a large outbreak was 34% (8–54). As the COVID-19 contact restrictions are nearly fully eased, from December 2020, the probability of a large measles outbreak will increase to 38% (19–54), 46% (30–59), and 54% (43–64) assuming a 15%, 50%, and 100% reduction in measles vaccination coverage. By December 2021, this risk increases further to 43% (25–56), 54% (43–63), and 67% (59–72) for the same coverage scenarios respectively. However, the increased risk of a measles outbreak following the lifting of all restrictions can be overcome by conducting a SIA with ≥ 95% coverage in under-fives. Conclusion While contact restrictions sufficient for SAR-CoV-2 control temporarily reduce measles transmissibility and the risk of an outbreak from a measles immunity gap, this risk rises rapidly once these restrictions are lifted. Implementing delayed SIAs will be critical for prevention of measles outbreaks given the roll-back of contact restrictions in Kenya.

Published

2020

26. What settings have been linked to SARS-CoV-2 transmission clusters?

Author

Leclerc, Quentin J, Fuller, Naomi M, Knight, Lisa E, CMMID COVID-19 Working Group, Funk, Sebastian, and Knight, Gwenan M

Abstract

Background: Concern about the health impact of novel coronavirus SARS-CoV-2 has resulted in widespread enforced reductions in people's movement ("lockdowns"). However, there are increasing concerns about the severe economic and wider societal consequences of these measures. Some countries have begun to lift some of the rules on physical distancing in a stepwise manner, with differences in what these "exit strategies" entail and their timeframes. The aim of this work was to inform such exit strategies by exploring the types of indoor and outdoor settings where transmission of SARS-CoV-2 has been reported to occur and result in clusters of cases. Identifying potential settings that result in transmission clusters allows these to be kept under close surveillance and/or to remain closed as part of strategies that aim to avoid a resurgence in transmission following the lifting of lockdown measures. Methods: We performed a systematic review of available literature and media reports to find settings reported in peer reviewed articles and media with these characteristics. These sources are curated and made available in an editable online database. Results: We found many examples of SARS-CoV-2 clusters linked to a wide range of mostly indoor settings. Few reports came from schools, many from households, and an increasing number were reported in hospitals and elderly care settings across Europe. Conclusions: We identified possible places that are linked to clusters of COVID-19 cases and could be closely monitored and/or remain closed in the first instance following the progressive removal of lockdown restrictions. However, in part due to the limits in surveillance capacities in many settings, the gathering of information such as cluster sizes and attack rates is limited in several ways: inherent recall bias, biased media reporting and missing data.

Published

2020

27. Feasibility of informing syndrome-level empiric antibiotic recommendations using publicly available antibiotic resistance datasets

Author

Medical Research Council (UK), Coll, Francesc [0000-0002-7882-2325], Leclerc, Quentin J., Naylor, Nichola R., Aiken, Alexander M., Coll, Francesc, Knight, Gwenan M., Medical Research Council (UK), Coll, Francesc [0000-0002-7882-2325], Leclerc, Quentin J., Naylor, Nichola R., Aiken, Alexander M., Coll, Francesc, and Knight, Gwenan M.

Abstract

Background: Antibiotics are often prescribed empirically to treat infection syndromes before causative bacteria and their susceptibility to antibiotics are identified. Guidelines on empiric antibiotic prescribing are key to effective treatment of infection syndromes, and need to be informed by likely bacterial aetiology and antibiotic resistance patterns. We aimed to create a clinically-relevant composite index of antibiotic resistance for common infection syndromes to inform recommendations at the national level. Methods: To create our index, we used open-access antimicrobial resistance (AMR) surveillance datasets, including the ECDC Surveillance Atlas, CDDEP ResistanceMap, WHO GLASS and the newly-available Pfizer ATLAS dataset. We integrated these with data on aetiology of common infection syndromes, existing empiric prescribing guidelines, and pricing and availability of antibiotics. Results: The ATLAS dataset covered many more bacterial species (287) and antibiotics (52) than other datasets (ranges = 8-11 and 16-32 respectively), but had a similar number of samples per country per year. Using these data, we were able to make empiric prescribing recommendations for bloodstream infection, pneumonia and cellulitis/skin abscess in up to 44 countries. There was insufficient data to make national-level recommendations for the other six syndromes investigated. Results are presented in an interactive web app, where users can visualise underlying resistance proportions to first-line empiric antibiotics for infection syndromes and countries of interest. Conclusions: We found that whilst the creation of a composite resistance index for empiric antibiotic therapy was technically feasible, the ATLAS dataset in its current form can only inform on a limited number of infection syndromes. Other open-access AMR surveillance datasets are largely limited to bloodstream infection specimens and cannot directly inform treatment of other syndromes. With improving availability of inter

Published

2020

28. Antimicrobial resistance and COVID-19: Intersections and implications

Author

Knight, Gwenan M, primary, Glover, Rebecca E, additional, McQuaid, C Finn, additional, Olaru, Ioana D, additional, Gallandat, Karin, additional, Leclerc, Quentin J, additional, Fuller, Naomi M, additional, Willcocks, Sam J, additional, Hasan, Rumina, additional, van Kleef, Esther, additional, and Chandler, Clare IR, additional

Published

2021

29. Comparing the Analysis and Results of a Modified Social Accounting Matrix Framework with Conventional Methods of Reporting Indirect Non-Medical Costs

Author

Standaert, Baudouin, primary, Sauboin, Christophe, additional, Leclerc, Quentin J., additional, and Connolly, Mark P., additional

Published

2020

30. Effectiveness of isolation, testing, contact tracing, and physical distancing on reducing transmission of SARS-CoV-2 in different settings: a mathematical modelling study

Author

Kucharski, Adam J, primary, Klepac, Petra, additional, Conlan, Andrew J K, additional, Kissler, Stephen M, additional, Tang, Maria L, additional, Fry, Hannah, additional, Gog, Julia R, additional, Edmunds, W John, additional, Emery, Jon C, additional, Medley, Graham, additional, Munday, James D, additional, Russell, Timothy W, additional, Leclerc, Quentin J, additional, Diamond, Charlie, additional, Procter, Simon R, additional, Gimma, Amy, additional, Sun, Fiona Yueqian, additional, Gibbs, Hamish P, additional, Rosello, Alicia, additional, van Zandvoort, Kevin, additional, Hué, Stéphane, additional, Meakin, Sophie R, additional, Deol, Arminder K, additional, Knight, Gwen, additional, Jombart, Thibaut, additional, Foss, Anna M, additional, Bosse, Nikos I, additional, Atkins, Katherine E, additional, Quilty, Billy J, additional, Lowe, Rachel, additional, Prem, Kiesha, additional, Flasche, Stefan, additional, Pearson, Carl A B, additional, Houben, Rein M G J, additional, Nightingale, Emily S, additional, Endo, Akira, additional, Tully, Damien C, additional, Liu, Yang, additional, Villabona-Arenas, Julian, additional, O'Reilly, Kathleen, additional, Funk, Sebastian, additional, Eggo, Rosalind M, additional, Jit, Mark, additional, Rees, Eleanor M, additional, Hellewell, Joel, additional, Clifford, Samuel, additional, Jarvis, Christopher I, additional, Abbott, Sam, additional, Auzenbergs, Megan, additional, Davies, Nicholas G, additional, and Simons, David, additional

Published

2020

31. Routine childhood immunisation during the COVID-19 pandemic in Africa: a benefit–risk analysis of health benefits versus excess risk of SARS-CoV-2 infection

Author

Abbas, Kaja, primary, Procter, Simon R, additional, van Zandvoort, Kevin, additional, Clark, Andrew, additional, Funk, Sebastian, additional, Mengistu, Tewodaj, additional, Hogan, Dan, additional, Dansereau, Emily, additional, Jit, Mark, additional, Flasche, Stefan, additional, Houben, Rein M G J, additional, Edmunds, W John, additional, Villabona-Arenas, Christian Julian, additional, Atkins, Katherine E, additional, Knight, Gwenan M, additional, Sun, Fiona Yueqian, additional, Auzenbergs, Megan, additional, Rosello, Alicia, additional, Klepac, Petra, additional, Hellewell, Joel, additional, Russell, Timothy W, additional, Tully, Damien C, additional, Emery, Jon C, additional, Gibbs, Hamish P, additional, Munday, James D, additional, Quilty, Billy J, additional, Diamond, Charlie, additional, Pearson, Carl A B, additional, Leclerc, Quentin J, additional, Nightingale, Emily S, additional, Liu, Yang, additional, Endo, Akira, additional, Deol, Arminder K, additional, Kucharski, Adam J, additional, Abbott, Sam, additional, Jarvis, Christopher I, additional, O'Reilly, Kathleen, additional, Jombart, Thibaut, additional, Gimma, Amy, additional, Bosse, Nikos I, additional, Prem, Kiesha, additional, Hué, Stéphane, additional, Davies, Nicholas G, additional, Eggo, Rosalind M, additional, Clifford, Samuel, additional, and Medley, Graham, additional

Published

2020

32. Global, regional, and national estimates of the population at increased risk of severe COVID-19 due to underlying health conditions in 2020: a modelling study

Author

Clark, Andrew, primary, Jit, Mark, additional, Warren-Gash, Charlotte, additional, Guthrie, Bruce, additional, Wang, Harry H X, additional, Mercer, Stewart W, additional, Sanderson, Colin, additional, McKee, Martin, additional, Troeger, Christopher, additional, Ong, Kanyin L, additional, Checchi, Francesco, additional, Perel, Pablo, additional, Joseph, Sarah, additional, Gibbs, Hamish P, additional, Banerjee, Amitava, additional, Eggo, Rosalind M, additional, Nightingale, Emily S, additional, O'Reilly, Kathleen, additional, Jombart, Thibaut, additional, Edmunds, W John, additional, Rosello, Alicia, additional, Sun, Fiona Yueqian, additional, Atkins, Katherine E, additional, Bosse, Nikos I, additional, Clifford, Samuel, additional, Russell, Timothy W, additional, Deol, Arminder K, additional, Liu, Yang, additional, Procter, Simon R, additional, Leclerc, Quentin J, additional, Medley, Graham, additional, Knight, Gwen, additional, Munday, James D, additional, Kucharski, Adam J, additional, Pearson, Carl A B, additional, Klepac, Petra, additional, Prem, Kiesha, additional, Houben, Rein M G J, additional, Endo, Akira, additional, Flasche, Stefan, additional, Davies, Nicholas G, additional, Diamond, Charlie, additional, van Zandvoort, Kevin, additional, Funk, Sebastian, additional, Auzenbergs, Megan, additional, Rees, Eleanor M, additional, Tully, Damien C, additional, Emery, Jon C, additional, Quilty, Billy J, additional, Abbott, Sam, additional, Villabona-Arenas, Ch Julian, additional, Hué, Stéphane, additional, Hellewell, Joel, additional, Gimma, Amy, additional, and Jarvis, Christopher I, additional

Published

2020

33. Feasibility of informing syndrome-level empiric antibiotic recommendations using publicly available antibiotic resistance datasets

Author

Leclerc, Quentin J., primary, Naylor, Nichola R., additional, Aiken, Alexander M., additional, Coll, Francesc, additional, and Knight, Gwenan M., additional

Published

2020

34. Feasibility of informing syndrome-level empiric antibiotic recommendations using publicly available antibiotic resistance datasets

Author

Leclerc, Quentin J., primary, Naylor, Nichola R., additional, Aiken, Alexander M., additional, Coll, Francesc, additional, and Knight, Gwenan M., additional

Published

2019

35. Mathematical modelling to study the horizontal transfer of antimicrobial resistance genes in bacteria: current state of the field and recommendations

Author

Leclerc, Quentin J., primary, Lindsay, Jodi A., additional, and Knight, Gwenan M., additional

Published

2019

36. The impact of non-pharmaceutical interventions on SARS-CoV-2 transmission across 130 countries and territories.

Author

Liu, Yang, Morgenstern, Christian, Kelly, James, Lowe, Rachel, CMMID COVID-19 Working Group, Munday, James, Villabona-Arenas, C. Julian, Gibbs, Hamish, Pearson, Carl A. B., Prem, Kiesha, Leclerc, Quentin J., Meakin, Sophie R., Edmunds, W. John, Jarvis, Christopher I., Gimma, Amy, Funk, Sebastian, Quaife, Matthew, Russell, Timothy W., Emory, Jon C., and Abbott, Sam

Subjects

COVID-19, SARS-CoV-2, COVID-19 pandemic, INFECTIOUS disease transmission, CONTACT tracing

Abstract

Background: Non-pharmaceutical interventions (NPIs) are used to reduce transmission of SARS coronavirus 2 (SARS-CoV-2) that causes coronavirus disease 2019 (COVID-19). However, empirical evidence of the effectiveness of specific NPIs has been inconsistent. We assessed the effectiveness of NPIs around internal containment and closure, international travel restrictions, economic measures, and health system actions on SARS-CoV-2 transmission in 130 countries and territories.Methods: We used panel (longitudinal) regression to estimate the effectiveness of 13 categories of NPIs in reducing SARS-CoV-2 transmission using data from January to June 2020. First, we examined the temporal association between NPIs using hierarchical cluster analyses. We then regressed the time-varying reproduction number (Rt) of COVID-19 against different NPIs. We examined different model specifications to account for the temporal lag between NPIs and changes in Rt, levels of NPI intensity, time-varying changes in NPI effect, and variable selection criteria. Results were interpreted taking into account both the range of model specifications and temporal clustering of NPIs.Results: There was strong evidence for an association between two NPIs (school closure, internal movement restrictions) and reduced Rt. Another three NPIs (workplace closure, income support, and debt/contract relief) had strong evidence of effectiveness when ignoring their level of intensity, while two NPIs (public events cancellation, restriction on gatherings) had strong evidence of their effectiveness only when evaluating their implementation at maximum capacity (e.g. restrictions on 1000+ people gathering were not effective, restrictions on < 10 people gathering were). Evidence about the effectiveness of the remaining NPIs (stay-at-home requirements, public information campaigns, public transport closure, international travel controls, testing, contact tracing) was inconsistent and inconclusive. We found temporal clustering between many of the NPIs. Effect sizes varied depending on whether or not we included data after peak NPI intensity.Conclusion: Understanding the impact that specific NPIs have had on SARS-CoV-2 transmission is complicated by temporal clustering, time-dependent variation in effects, and differences in NPI intensity. However, the effectiveness of school closure and internal movement restrictions appears robust across different model specifications, with some evidence that other NPIs may also be effective under particular conditions. This provides empirical evidence for the potential effectiveness of many, although not all, actions policy-makers are taking to respond to the COVID-19 pandemic. [ABSTRACT FROM AUTHOR]

Published

2021

37. Correction for Leclerc et al., “Growth-Dependent Predation and Generalized Transduction of Antimicrobial Resistance by Bacteriophage”.

Author

Leclerc, Quentin J., Wildfire, Jacob, Gupta, Arya, Lindsay, Jodi A., and Knight, Gwenan M.

Published

2022

38. The impact of COVID-19 control measures on social contacts and transmission in Kenyan informal settlements.

Author

Quaife, Matthew, van Zandvoort, Kevin, Gimma, Amy, Shah, Kashvi, McCreesh, Nicky, Prem, Kiesha, Barasa, Edwine, Mwanga, Daniel, Kangwana, Beth, Pinchoff, Jessie, CMMID COVID-19 Working Group, Bosse, Nikos I., Medley, Graham, O'Reilly, Kathleen, Leclerc, Quentin J., Jit, Mark, Lowe, Rachel, Davies, Nicholas G., Deol, Arminder K., and Knight, Gwenan M.

Subjects

COVID-19, SOCIAL contact, SOCIAL control, BASIC reproduction number, SOCIAL surveys

Abstract

Background: Many low- and middle-income countries have implemented control measures against coronavirus disease 2019 (COVID-19). However, it is not clear to what extent these measures explain the low numbers of recorded COVID-19 cases and deaths in Africa. One of the main aims of control measures is to reduce respiratory pathogen transmission through direct contact with others. In this study, we collect contact data from residents of informal settlements around Nairobi, Kenya, to assess if control measures have changed contact patterns, and estimate the impact of changes on the basic reproduction number (R0).Methods: We conducted a social contact survey with 213 residents of five informal settlements around Nairobi in early May 2020, 4 weeks after the Kenyan government introduced enhanced physical distancing measures and a curfew between 7 pm and 5 am. Respondents were asked to report all direct physical and non-physical contacts made the previous day, alongside a questionnaire asking about the social and economic impact of COVID-19 and control measures. We examined contact patterns by demographic factors, including socioeconomic status. We described the impact of COVID-19 and control measures on income and food security. We compared contact patterns during control measures to patterns from non-pandemic periods to estimate the change in R0.Results: We estimate that control measures reduced physical contacts by 62% and non-physical contacts by either 63% or 67%, depending on the pre-COVID-19 comparison matrix used. Masks were worn by at least one person in 92% of contacts. Respondents in the poorest socioeconomic quintile reported 1.5 times more contacts than those in the richest. Eighty-six percent of respondents reported a total or partial loss of income due to COVID-19, and 74% reported eating less or skipping meals due to having too little money for food.Conclusion: COVID-19 control measures have had a large impact on direct contacts and therefore transmission, but have also caused considerable economic and food insecurity. Reductions in R0 are consistent with the comparatively low epidemic growth in Kenya and other sub-Saharan African countries that implemented similar, early control measures. However, negative and inequitable impacts on economic and food security may mean control measures are not sustainable in the longer term. [ABSTRACT FROM AUTHOR]

Published

2020

39. Importance of patient bed pathways and length of stay differences in predicting COVID-19 hospital bed occupancy in England

Author

Leclerc, Quentin J, Fuller, Naomi M, Keogh, Ruth H, Diaz-Ordaz, Karla, Sekula, Richard, Semple, Malcolm G, ISARIC4C Investigators, CMMID COVID-19 Working Group, Atkins, Katherine E, Procter, Simon R, and Knight, Gwenan M

Subjects

England, SARS-CoV-2, Hospitalisation, Bed pathway, COVID-19, Length of stay, Humans, Bed occupancy, 3. Good health

Abstract

BACKGROUND: Predicting bed occupancy for hospitalised patients with COVID-19 requires understanding of length of stay (LoS) in particular bed types. LoS can vary depending on the patient's "bed pathway" - the sequence of transfers of individual patients between bed types during a hospital stay. In this study, we characterise these pathways, and their impact on predicted hospital bed occupancy. METHODS: We obtained data from University College Hospital (UCH) and the ISARIC4C COVID-19 Clinical Information Network (CO-CIN) on hospitalised patients with COVID-19 who required care in general ward or critical care (CC) beds to determine possible bed pathways and LoS. We developed a discrete-time model to examine the implications of using either bed pathways or only average LoS by bed type to forecast bed occupancy. We compared model-predicted bed occupancy to publicly available bed occupancy data on COVID-19 in England between March and August 2020. RESULTS: In both the UCH and CO-CIN datasets, 82% of hospitalised patients with COVID-19 only received care in general ward beds. We identified four other bed pathways, present in both datasets: "Ward, CC, Ward", "Ward, CC", "CC" and "CC, Ward". Mean LoS varied by bed type, pathway, and dataset, between 1.78 and 13.53 days. For UCH, we found that using bed pathways improved the accuracy of bed occupancy predictions, while only using an average LoS for each bed type underestimated true bed occupancy. However, using the CO-CIN LoS dataset we were not able to replicate past data on bed occupancy in England, suggesting regional LoS heterogeneities. CONCLUSIONS: We identified five bed pathways, with substantial variation in LoS by bed type, pathway, and geography. This might be caused by local differences in patient characteristics, clinical care strategies, or resource availability, and suggests that national LoS averages may not be appropriate for local forecasts of bed occupancy for COVID-19. TRIAL REGISTRATION: The ISARIC WHO CCP-UK study ISRCTN66726260 was retrospectively registered on 21/04/2020 and designated an Urgent Public Health Research Study by NIHR.

40. Modelling the medium-term dynamics of SARS-CoV-2 transmission in England in the Omicron era

Author

Barnard, Rosanna C., Davies, Nicholas G., Munday, James D., Lowe, Rachel, Knight, Gwenan M., Leclerc, Quentin J., Tully, Damien C., Hodgson, David, Pung, Rachael, Hellewell, Joel, Koltai, Mihaly, Simons, David, Abbas, Kaja, Kucharski, Adam J., Procter, Simon R., Sandmann, Frank G., Pearson, Carl A. B., Prem, Kiesha, Showering, Alicia, Meakin, Sophie R., O’Reilly, Kathleen, McCarthy, Ciara V., Quaife, Matthew, Wong, Kerry L. M., Jafari, Yalda, Deol, Arminder K., Houben, Rein M. G. J., Diamond, Charlie, Jombart, Thibaut, Villabona-Arenas, C. Julian, Waites, William, Eggo, Rosalind M., Endo, Akira, Gibbs, Hamish P., Klepac, Petra, Williams, Jack, Quilty, Billy J., Brady, Oliver, Emery, Jon C., Atkins, Katherine E., Chapman, Lloyd A. C., Sherratt, Katharine, Abbott, Sam, Bosse, Nikos I., Mee, Paul, Funk, Sebastian, Lei, Jiayao, Liu, Yang, Flasche, Stefan, Rudge, James W., Sun, Fiona Yueqian, Medley, Graham, Russell, Timothy W., Gimma, Amy, Hué, Stéphane, Jarvis, Christopher I., Finch, Emilie, Clifford, Samuel, Jit, Mark, and Edmunds, W. John

Subjects

Multidisciplinary, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology

Abstract

England has experienced a heavy burden of COVID-19, with multiple waves of SARS-CoV-2 transmission since early 2020 and high infection levels following the emergence and spread of Omicron variants since late 2021. In response to rising Omicron cases, booster vaccinations were accelerated and offered to all adults in England. Using a model fitted to more than 2 years of epidemiological data, we project potential dynamics of SARS-CoV-2 infections, hospital admissions and deaths in England to December 2022. We consider key uncertainties including future behavioural change and waning immunity and assess the effectiveness of booster vaccinations in mitigating SARS-CoV-2 disease burden between October 2021 and December 2022. If no new variants emerge, SARS-CoV-2 transmission is expected to decline, with low levels remaining in the coming months. The extent to which projected SARS-CoV-2 transmission resurges later in 2022 depends largely on assumptions around waning immunity and to some extent, behaviour, and seasonality.

41. Importance of patient bed pathways and length of stay differences in predicting COVID-19 hospital bed occupancy in England

Author

Alexander Mentzer, David Brealey, Paul Collini, Mahdad Noursadeghi, Charlotte Summers, Graciela Isabel García Dorival, Andrew Ustianowski, Damien Tully, Lorna Finch, Innocent Gerald Asiimwe, Stuart Hartshorn, Gary Leeming, Lance Turtle, Quentin Leclerc, Thushan De Silva, Lauren Lett, Chris Davis, Christopher Jarvis, Wei Shen Lim, Malcolm Gracie Semple, Tom Fletcher, Katie Ahmed, Manu Shankar-Hari, Wendy Barclay, Ruth Keogh, Chrysa Koukorava, Patrick Lillie, Ingeborg Welters, Suzannah Lant, Paul Klenerman, Stefan Flasche, Louise Sigfrid, Mark Jit, Anil Sharma, Billy Quilty, Rebecca Jensen, Effrossyni Gkrania-Klotsas, Robyn Kiy, Ahilanandan Dushianthan, Graham Medley, Christopher Green, Mark Peters, Paul Dark, Luke Hodgson, Emma Thomson, Kenneth A McLean, Yang Liu, Matthew Quaife, William Paxton, Ascanio Tridente, Shona Moore, Simon Procter, Dan Hawcutt, Christian Julian Villabona Arenas, Investigators, ISARIC4C, Group, CMMID COVID-19 Working, Leclerc, Quentin J [0000-0003-4761-001X], Apollo - University of Cambridge Repository, UK Research and Innovation, National Institute for Health Research, and UKRI MRC COVID-19 Rapid Response Call

Subjects

medicine.medical_specialty, Occupancy, Coronavirus disease 2019 (COVID-19), CMMID COVID-19 Working Group, Hospital bed, 1110 Nursing, 030204 cardiovascular system & hematology, Bed occupancy, 1117 Public Health and Health Services, Health administration, 03 medical and health sciences, 0302 clinical medicine, Hospitalisation, medicine, Humans, Bed pathway, In patient, 030212 general & internal medicine, Trial registration, ISARIC4C Investigators, SARS-CoV-2, business.industry, Health Policy, COVID-19, Bed Occupancy, 3. Good health, England, Emergency medicine, Health Policy & Services, Length of stay, Public aspects of medicine, RA1-1270, General ward, business, 0807 Library and Information Studies, Research Article

Abstract

Background Predicting bed occupancy for hospitalised patients with COVID-19 requires understanding of length of stay (LoS) in particular bed types. LoS can vary depending on the patient’s “bed pathway” - the sequence of transfers of individual patients between bed types during a hospital stay. In this study, we characterise these pathways, and their impact on predicted hospital bed occupancy. Methods We obtained data from University College Hospital (UCH) and the ISARIC4C COVID-19 Clinical Information Network (CO-CIN) on hospitalised patients with COVID-19 who required care in general ward or critical care (CC) beds to determine possible bed pathways and LoS. We developed a discrete-time model to examine the implications of using either bed pathways or only average LoS by bed type to forecast bed occupancy. We compared model-predicted bed occupancy to publicly available bed occupancy data on COVID-19 in England between March and August 2020. Results In both the UCH and CO-CIN datasets, 82% of hospitalised patients with COVID-19 only received care in general ward beds. We identified four other bed pathways, present in both datasets: “Ward, CC, Ward”, “Ward, CC”, “CC” and “CC, Ward”. Mean LoS varied by bed type, pathway, and dataset, between 1.78 and 13.53 days. For UCH, we found that using bed pathways improved the accuracy of bed occupancy predictions, while only using an average LoS for each bed type underestimated true bed occupancy. However, using the CO-CIN LoS dataset we were not able to replicate past data on bed occupancy in England, suggesting regional LoS heterogeneities. Conclusions We identified five bed pathways, with substantial variation in LoS by bed type, pathway, and geography. This might be caused by local differences in patient characteristics, clinical care strategies, or resource availability, and suggests that national LoS averages may not be appropriate for local forecasts of bed occupancy for COVID-19. Trial registration The ISARIC WHO CCP-UK study ISRCTN66726260 was retrospectively registered on 21/04/2020 and designated an Urgent Public Health Research Study by NIHR.

Published

2021

42. Real-time monitoring of COVID-19 dynamics using automated trend fitting and anomaly detection.

Author

Jombart T, Ghozzi S, Schumacher D, Taylor TJ, Leclerc QJ, Jit M, Flasche S, Greaves F, Ward T, Eggo RM, Nightingale E, Meakin S, Brady OJ, Medley GF, Höhle M, and Edmunds WJ

Subjects

Algorithms, COVID-19 transmission, COVID-19 virology, Communicable Disease Control, England epidemiology, Humans, United Kingdom epidemiology, COVID-19 epidemiology, Models, Theoretical, Pandemics, SARS-CoV-2 pathogenicity

Abstract

As several countries gradually release social distancing measures, rapid detection of new localized COVID-19 hotspots and subsequent intervention will be key to avoiding large-scale resurgence of transmission. We introduce ASMODEE (automatic selection of models and outlier detection for epidemics), a new tool for detecting sudden changes in COVID-19 incidence. Our approach relies on automatically selecting the best (fitting or predicting) model from a range of user-defined time series models, excluding the most recent data points, to characterize the main trend in an incidence. We then derive prediction intervals and classify data points outside this interval as outliers, which provides an objective criterion for identifying departures from previous trends. We also provide a method for selecting the optimal breakpoints, used to define how many recent data points are to be excluded from the trend fitting procedure. The analysis of simulated COVID-19 outbreaks suggests ASMODEE compares favourably with a state-of-art outbreak-detection algorithm while being simpler and more flexible. As such, our method could be of wider use for infectious disease surveillance. We illustrate ASMODEE using publicly available data of National Health Service (NHS) Pathways reporting potential COVID-19 cases in England at a fine spatial scale, showing that the method would have enabled the early detection of the flare-ups in Leicester and Blackburn with Darwen, two to three weeks before their respective lockdown. ASMODEE is implemented in the free R package trendbreaker . This article is part of the theme issue 'Modelling that shaped the early COVID-19 pandemic response in the UK'.

Published

2021

43. Importance of patient bed pathways and length of stay differences in predicting COVID-19 hospital bed occupancy in England.

Author

Leclerc QJ, Fuller NM, Keogh RH, Diaz-Ordaz K, Sekula R, Semple MG, Atkins KE, Procter SR, and Knight GM

Subjects

England, Humans, Length of Stay, SARS-CoV-2, Bed Occupancy, COVID-19

Abstract

Background: Predicting bed occupancy for hospitalised patients with COVID-19 requires understanding of length of stay (LoS) in particular bed types. LoS can vary depending on the patient's "bed pathway" - the sequence of transfers of individual patients between bed types during a hospital stay. In this study, we characterise these pathways, and their impact on predicted hospital bed occupancy., Methods: We obtained data from University College Hospital (UCH) and the ISARIC4C COVID-19 Clinical Information Network (CO-CIN) on hospitalised patients with COVID-19 who required care in general ward or critical care (CC) beds to determine possible bed pathways and LoS. We developed a discrete-time model to examine the implications of using either bed pathways or only average LoS by bed type to forecast bed occupancy. We compared model-predicted bed occupancy to publicly available bed occupancy data on COVID-19 in England between March and August 2020., Results: In both the UCH and CO-CIN datasets, 82% of hospitalised patients with COVID-19 only received care in general ward beds. We identified four other bed pathways, present in both datasets: "Ward, CC, Ward", "Ward, CC", "CC" and "CC, Ward". Mean LoS varied by bed type, pathway, and dataset, between 1.78 and 13.53 days. For UCH, we found that using bed pathways improved the accuracy of bed occupancy predictions, while only using an average LoS for each bed type underestimated true bed occupancy. However, using the CO-CIN LoS dataset we were not able to replicate past data on bed occupancy in England, suggesting regional LoS heterogeneities., Conclusions: We identified five bed pathways, with substantial variation in LoS by bed type, pathway, and geography. This might be caused by local differences in patient characteristics, clinical care strategies, or resource availability, and suggests that national LoS averages may not be appropriate for local forecasts of bed occupancy for COVID-19., Trial Registration: The ISARIC WHO CCP-UK study ISRCTN66726260 was retrospectively registered on 21/04/2020 and designated an Urgent Public Health Research Study by NIHR.

Published

2021

44. Implication of backward contact tracing in the presence of overdispersed transmission in COVID-19 outbreaks.

Author

Endo A, Leclerc QJ, Knight GM, Medley GF, Atkins KE, Funk S, and Kucharski AJ

Abstract

Introduction: Contact tracing has the potential to control outbreaks without the need for stringent physical distancing policies, e.g. civil lockdowns. Unlike forward contact tracing, backward contact tracing identifies the source of newly detected cases. This approach is particularly valuable when there is high individual-level variation in the number of secondary transmissions (overdispersion). Methods: By using a simple branching process model, we explored the potential of combining backward contact tracing with more conventional forward contact tracing for control of COVID-19. We estimated the typical size of clusters that can be reached by backward tracing and simulated the incremental effectiveness of combining backward tracing with conventional forward tracing. Results: Across ranges of parameter values consistent with dynamics of SARS-CoV-2, backward tracing is expected to identify a primary case generating 3-10 times more infections than a randomly chosen case, typically increasing the proportion of subsequent cases averted by a factor of 2-3. The estimated number of cases averted by backward tracing became greater with a higher degree of overdispersion. Conclusion: Backward contact tracing can be an effective tool for outbreak control, especially in the presence of overdispersion as is observed with SARS-CoV-2., Competing Interests: Competing interests: AE received a research grant from Taisho Pharmaceutical Co., Ltd., (Copyright: © 2021 Endo A et al.)

Published

2021

45. Analysis of temporal trends in potential COVID-19 cases reported through NHS Pathways England.

Author

Leclerc QJ, Nightingale ES, Abbott S, and Jombart T

Subjects

COVID-19 virology, England epidemiology, Humans, SARS-CoV-2 isolation & purification, State Medicine, COVID-19 epidemiology

Abstract

The National Health Service (NHS) Pathways triage system collates data on enquiries to 111 and 999 services in England. Since the 18th of March 2020, these data have been made publically available for potential COVID-19 symptoms self-reported by members of the public. Trends in such reports over time are likely to reflect behaviour of the ongoing epidemic within the wider community, potentially capturing valuable information across a broader severity profile of cases than hospital admission data. We present a fully reproducible analysis of temporal trends in NHS Pathways reports until 14th May 2020, nationally and regionally, and demonstrate that rates of growth/decline and effective reproduction number estimated from these data may be useful in monitoring transmission. This is a particularly pressing issue as lockdown restrictions begin to be lifted and evidence of disease resurgence must be constantly reassessed. We further assess the correlation between NHS Pathways reports and a publicly available NHS dataset of COVID-19-associated deaths in England, finding that enquiries to 111/999 were strongly associated with daily deaths reported 16 days later. Our results highlight the potential of NHS Pathways as the basis of an early warning system. However, this dataset relies on self-reported symptoms, which are at risk of being severely biased. Further detailed work is therefore necessary to investigate potential behavioural issues which might otherwise explain our conclusions.

Published

2021

46. Implication of backward contact tracing in the presence of overdispersed transmission in COVID-19 outbreaks.

Author

Endo A, Leclerc QJ, Knight GM, Medley GF, Atkins KE, Funk S, and Kucharski AJ

Abstract

Introduction: Contact tracing has the potential to control outbreaks without the need for stringent physical distancing policies, e.g. civil lockdowns. Unlike forward contact tracing, backward contact tracing identifies the source of newly detected cases. This approach is particularly valuable when there is high individual-level variation in the number of secondary transmissions (overdispersion). Methods: By using a simple branching process model, we explored the potential of combining backward contact tracing with more conventional forward contact tracing for control of COVID-19. We estimated the typical size of clusters that can be reached by backward tracing and simulated the incremental effectiveness of combining backward tracing with conventional forward tracing. Results: Across ranges of parameter values consistent with dynamics of SARS-CoV-2, backward tracing is expected to identify a primary case generating 3-10 times more infections than average, typically increasing the proportion of subsequent cases averted by a factor of 2-3. The estimated number of cases averted by backward tracing became greater with a higher degree of overdispersion. Conclusion: Backward contact tracing can be an effective tool for outbreak control, especially in the presence of overdispersion as was observed with SARS-CoV-2., Competing Interests: Competing interests: AE received a research grant from Taisho Pharmaceutical Co., Ltd., (Copyright: © 2020 Endo A et al.)

Published

2020

47. What settings have been linked to SARS-CoV-2 transmission clusters?

Author

Leclerc QJ, Fuller NM, Knight LE, Funk S, and Knight GM

Abstract

Background : Concern about the health impact of novel coronavirus SARS-CoV-2 has resulted in widespread enforced reductions in people's movement ("lockdowns"). However, there are increasing concerns about the severe economic and wider societal consequences of these measures. Some countries have begun to lift some of the rules on physical distancing in a stepwise manner, with differences in what these "exit strategies" entail and their timeframes. The aim of this work was to inform such exit strategies by exploring the types of indoor and outdoor settings where transmission of SARS-CoV-2 has been reported to occur and result in clusters of cases. Identifying potential settings that result in transmission clusters allows these to be kept under close surveillance and/or to remain closed as part of strategies that aim to avoid a resurgence in transmission following the lifting of lockdown measures. Methods : We performed a systematic review of available literature and media reports to find settings reported in peer reviewed articles and media with these characteristics. These sources are curated and made available in an editable online database. Results : We found many examples of SARS-CoV-2 clusters linked to a wide range of mostly indoor settings. Few reports came from schools, many from households, and an increasing number were reported in hospitals and elderly care settings across Europe. Conclusions: We identified possible places that are linked to clusters of COVID-19 cases and could be closely monitored and/or remain closed in the first instance following the progressive removal of lockdown restrictions. However, in part due to the limits in surveillance capacities in many settings, the gathering of information such as cluster sizes and attack rates is limited in several ways: inherent recall bias, biased media reporting and missing data., Competing Interests: No competing interests were disclosed., (Copyright: © 2020 Leclerc QJ et al.)

Published

2020