Your search keyword '"Louise Dyson"' showing total 96 results

1. Emergence of SARS-CoV-2 Delta Variant and Effect of Nonpharmaceutical Interventions, British Columbia, Canada

Author

Y.L. Elaine Chan, Michael A. Irvine, Natalie Prystajecky, Hind Sbihi, Marsha Taylor, Yayuk Joffres, Andrea Schertzer, Caren Rose, Louise Dyson, Edward M. Hill, Michael Tildesley, John R. Tyson, Linda M.N. Hoang, and Eleni Galanis

Subjects

COVID-19, SARS-CoV-2, B.1.617.2 SARS-CoV-2 variant, SARS-CoV-2 Delta variant, communicable disease control, disease transmission, Medicine, Infectious and parasitic diseases, RC109-216

Abstract

In British Columbia, Canada, initial growth of the SARS-CoV-2 Delta variant was slower than that reported in other jurisdictions. Delta became the dominant variant (>50% prevalence) within ≈7–13 weeks of first detection in regions within the United Kingdom and United States. In British Columbia, it remained at

Published

2023

2. Comparison of the 2021 COVID-19 roadmap projections against public health data in England

Author

Matt J. Keeling, Louise Dyson, Michael J. Tildesley, Edward M. Hill, and Samuel Moore

Subjects

Science

Abstract

The ’Roadmap’ for relaxation of COVID-19 restrictions in England in 2021 was informed by mathematical modelling. Here, the authors perform a retrospective assessment of the accuracy of modelling predictions and identify the main sources of uncertainty that led to observed values deviating from projections.

Published

2022

3. Quantifying pupil-to-pupil SARS-CoV-2 transmission and the impact of lateral flow testing in English secondary schools

Author

Trystan Leng, Edward M. Hill, Alex Holmes, Emma Southall, Robin N. Thompson, Michael J. Tildesley, Matt J. Keeling, and Louise Dyson

Subjects

Science

Abstract

Twice weekly mass testing using lateral flow tests has helped to control pupil-to-pupil transmission in English secondary schools. Here, the authors show that repeat testing of contacts alongside mass testing could greatly reduce absences with only a marginal increase in transmission, compared to isolating contacts.

Published

2022

4. Interview: Louise Dyson

Author

Louise Dyson

Subjects

Infectious and parasitic diseases, RC109-216, Microbiology, QR1-502

Published

2023

5. The risk of SARS-CoV-2 outbreaks in low prevalence settings following the removal of travel restrictions

Author

Rahil Sachak-Patwa, Helen M. Byrne, Louise Dyson, and Robin N. Thompson

Subjects

Medicine

Abstract

Plain language summary The effectiveness of public health measures against COVID-19 has varied between countries, with some experiencing many infections and others containing transmission successfully. As vaccines are deployed, an important challenge is deciding when to relax measures. Here, we consider locations with few cases, and investigate whether vaccination can ever eliminate the risk of COVID-19 outbreaks completely, allowing measures to be removed risk-free. Using a mathematical model, we demonstrate that there is still a risk that imported cases initiate outbreaks when measures are removed, even if most of the population is fully vaccinated. This highlights the need for continued vigilance in low prevalence settings to prevent imported cases leading to local transmission. Until case numbers are reduced globally, so that SARS-CoV-2 spread between countries is less likely, the risk of outbreaks in low prevalence settings will remain.

Published

2021

6. Possible future waves of SARS-CoV-2 infection generated by variants of concern with a range of characteristics

Author

Louise Dyson, Edward M. Hill, Sam Moore, Jacob Curran-Sebastian, Michael J. Tildesley, Katrina A. Lythgoe, Thomas House, Lorenzo Pellis, and Matt J. Keeling

Subjects

Science

Abstract

Understanding the potential impacts of new variants of SARS-CoV-2 is important for pandemic planning. Here, the authors develop a model incorporating hypothetical new variants with varying transmissibility and immune evasion properties, and use it to project possible future epidemic waves in the UK.

Published

2021

7. Diagnostics to support the eradication of yaws-Development of two target product profiles.

Author

Noah Fongwen, Becca L Handley, Diana L Martin, Camila Beiras, Louise Dyson, Michael Frimpong, Oriol Mitja, Kingsley Asiedu, and Michael Marks

Subjects

Arctic medicine. Tropical medicine, RC955-962, Public aspects of medicine, RA1-1270

Abstract

BackgroundYaws is targeted for eradication by 2030, using a strategy based on mass drug administration (MDA) with azithromycin. New diagnostics are needed to aid eradication. Serology is currently the mainstay for yaws diagnosis; however, inaccuracies associated with current serological tests makes it difficult to fully assess the need for and impact of eradication campaigns using these tools. Under the recommendation of the WHO Diagnostic Technical Advisory Group (DTAG) for Neglected Tropical Diseases(NTDs), a working group was assembled and tasked with agreeing on priority use cases for developing target product profiles (TPPs) for new diagnostics tools.Methodology and principal findingsThe working group convened three times and established two use cases: identifying a single case of yaws and detecting azithromycin resistance. One subgroup assessed the current diagnostic landscape for yaws and a second subgroup determined the test requirements for both use cases. Draft TPPs were sent out for input from stakeholders and experts. Both TPPs considered the following parameters: product use, design, performance, configuration, cost, access and equity. To identify a single case of yaws, the test should be able to detect an analyte which confirms an active infection with at least 95% sensitivity and 99.9% specificity. The high specificity was deemed important to avoid a high false positive rate which could result in unnecessary continuation or initiation of MDA campaigns. If used in settings where the number of suspected cases is low, further testing could be considered to compensate for imperfect sensitivity and to improve specificity. The test to detect azithromycin resistance should be able to detect known genetic resistance mutations with a minimum sensitivity and specificity of 95%, with the caveat that all patients with suspected treatment failure should be treated as having resistant yaws and offered alternative treatment.ConclusionsThe TPPs developed will provide test developers with guidance to ensure that novel diagnostic tests meet identified public health needs.

Published

2022

8. Optimal health and economic impact of non-pharmaceutical intervention measures prior and post vaccination in England: a mathematical modelling study

Author

Michael J. Tildesley, Anna Vassall, Steven Riley, Mark Jit, Frank Sandmann, Edward M. Hill, Robin N. Thompson, Benjamin D. Atkins, John Edmunds, Louise Dyson, and Matt J. Keeling

Subjects

health, economic, policy, disease control, optimization, Science

Abstract

Background. Even with good progress on vaccination, SARS-CoV-2 infections in the UK may continue to impose a high burden of disease and therefore pose substantial challenges for health policy decision makers. Stringent government-mandated physical distancing measures (lockdown) have been demonstrated to be epidemiologically effective, but can have both positive and negative economic consequences. The duration and frequency of any intervention policy could, in theory, be optimized to maximize economic benefits while achieving substantial reductions in disease. Methods. Here, we use a pre-existing SARS-CoV-2 transmission model to assess the health and economic implications of different strengths of control through time in order to identify optimal approaches to non-pharmaceutical intervention stringency in the UK, considering the role of vaccination in reducing the need for future physical distancing measures. The model is calibrated to the COVID-19 epidemic in England and we carry out retrospective analysis of the optimal timing of precautionary breaks in 2020 and the optimal relaxation policy from the January 2021 lockdown, considering the willingness to pay (WTP) for health improvement. Results. We find that the precise timing and intensity of interventions is highly dependent upon the objective of control. As intervention measures are relaxed, we predict a resurgence in cases, but the optimal intervention policy can be established dependent upon the WTP per quality adjusted life year loss avoided. Our results show that establishing an optimal level of control can result in a reduction in net monetary loss of billions of pounds, dependent upon the precise WTP value. Conclusion. It is vital, as the UK emerges from lockdown, but continues to face an on-going pandemic, to accurately establish the overall health and economic costs when making policy decisions. We demonstrate how some of these can be quantified, employing mechanistic infectious disease transmission models to establish optimal levels of control for the ongoing COVID-19 pandemic.

Published

2022

9. An analysis of school absences in England during the COVID-19 pandemic

Author

Emma Southall, Alex Holmes, Edward M. Hill, Benjamin D. Atkins, Trystan Leng, Robin N. Thompson, Louise Dyson, Matt J. Keeling, and Michael J. Tildesley

Subjects

SARS-CoV-2, COVID-19, Schools, Children, Medicine

Abstract

Abstract Background The introduction of SARS-CoV-2, the virus that causes COVID-19 infection, in the UK in early 2020, resulted in the introduction of several control policies to reduce disease spread. As part of these restrictions, schools were closed to all pupils in March (except for vulnerable and key worker children), before re-opening to certain year groups in June. Finally, all school children returned to the classroom in September. Methods Here, we analyse data on school absences in late 2020 as a result of COVID-19 infection and how that varied through time as other measures in the community were introduced. We utilise data from the Department for Education Educational Settings database and examine how pupil and teacher absences change in both primary and secondary schools. Results Our results show that absences as a result of COVID-19 infection rose steadily following the re-opening of schools in September. Cases in teachers declined during the November lockdown, particularly in regions previously in tier 3, the highest level of control at the time. Cases in secondary school pupils increased for the first 2 weeks of the November lockdown, before decreasing. Since the introduction of the tier system, the number of absences with confirmed infection in primary schools was observed to be (markedly) lower than that in secondary schools. In December, we observed a large rise in the number of absences per school in secondary school settings in the South East and London, but such rises were not observed in other regions or in primary school settings. We conjecture that the increased transmissibility of the new variant in these regions may have contributed to this rise in secondary school cases. Finally, we observe a positive correlation between cases in the community and cases in schools in most regions, with weak evidence suggesting that cases in schools lag behind cases in the surrounding community. Conclusions We conclude that there is no significant evidence to suggest that schools are playing a substantial role in driving spread in the community and that careful monitoring may be required as schools re-open to determine the effect associated with open schools upon community incidence.

Published

2021

10. Assessing the impact of lateral flow testing strategies on within-school SARS-CoV-2 transmission and absences: A modelling study.

Author

Trystan Leng, Edward M Hill, Robin N Thompson, Michael J Tildesley, Matt J Keeling, and Louise Dyson

Subjects

Biology (General), QH301-705.5

Abstract

Rapid testing strategies that replace the isolation of close contacts through the use of lateral flow device tests (LFTs) have been suggested as a way of controlling SARS-CoV-2 transmission within schools that maintain low levels of pupil absences. We developed an individual-based model of a secondary school formed of exclusive year group bubbles (five year groups, with 200 pupils per year) to assess the likely impact of strategies using LFTs in secondary schools over the course of a seven-week half-term on transmission, absences, and testing volume, compared to a policy of isolating year group bubbles upon a pupil returning a positive polymerase chain reaction (PCR) test. We also considered the sensitivity of results to levels of participation in rapid testing and underlying model assumptions. While repeated testing of year group bubbles following case detection is less effective at reducing infections than a policy of isolating year group bubbles, strategies involving twice weekly mass testing can reduce infections to lower levels than would occur under year group isolation. By combining regular testing with serial contact testing or isolation, infection levels can be reduced further still. At high levels of pupil participation in lateral flow testing, strategies replacing the isolation of year group bubbles with testing substantially reduce absences, but require a high volume of testing. Our results highlight the conflict between the goals of minimising within-school transmission, minimising absences and minimising testing burden. While rapid testing strategies can reduce school transmission and absences, they may lead to a large number of daily tests.

Published

2022

11. Modeling Treatment Strategies to Inform Yaws Eradication

Author

Alex Holmes, Michael J. Tildesley, Anthony W. Solomon, David C.W. Mabey, Oliver Sokana, Michael Marks, and Louise Dyson

Subjects

yaws, mass drug administration, Treponema pallidum pertenue, contact tracing, bacteria, bacterial infections, Medicine, Infectious and parasitic diseases, RC109-216

Abstract

Yaws is a neglected tropical disease targeted for eradication by 2030. To achieve eradication, finding and treating asymptomatic infections as well as clinical cases is crucial. The proposed plan, the Morges strategy, involves rounds of total community treatment (i.e., treating the whole population) and total targeted treatment (TTT) (i.e., treating clinical cases and contacts). However, modeling and empirical work suggests asymptomatic infections often are not found in the same households as clinical cases, reducing the utility of household-based contact tracing for a TTT strategy. We use a model fitted to data from the Solomon Islands to predict the likelihood of elimination of transmission under different intervention schemes and levels of systematic nontreatment resulting from the intervention. Our results indicate that implementing additional treatment rounds through total community treatment is more effective than conducting additional rounds of treatment of at-risk persons through TTT.

Published

2020

12. How modelling can help steer the course set by the World Health Organization 2021-2030 roadmap on neglected tropical diseases [version 2; peer review: 2 approved]

Author

Michael Marks, Louise Dyson, Wilma A. Stolk, Jessica Clark, Zulma M. Cucunubá, María-Gloria Basáñez, Timothy M. Pollington, Matthew A. Dixon, Kat S. Rock, Luc E. Coffeng, Joaquin M. Prada, Jaspreet Toor, Graham F. Medley, Henrik Salje, T. Déirdre Hollingsworth, and Katie Hampson

Subjects

Mathematical, Statistical, Targets, Public Health, Elimination, Transmission, eng, Medicine

Abstract

The World Health Organization recently launched its 2021-2030 roadmap, Ending the Neglect to Attain the Sustainable Development Goals, an updated call to arms to end the suffering caused by neglected tropical diseases. Modelling and quantitative analyses played a significant role in forming these latest goals. In this collection, we discuss the insights, the resulting recommendations and identified challenges of public health modelling for 13 of the target diseases: Chagas disease, dengue, gambiense human African trypanosomiasis (gHAT), lymphatic filariasis (LF), onchocerciasis, rabies, scabies, schistosomiasis, soil-transmitted helminthiases (STH), Taenia solium taeniasis/ cysticercosis, trachoma, visceral leishmaniasis (VL) and yaws. This piece reflects the three cross-cutting themes identified across the collection, regarding the contribution that modelling can make to timelines, programme design, drug development and clinical trials.

Published

2022

13. Precautionary breaks: Planned, limited duration circuit breaks to control the prevalence of SARS-CoV2 and the burden of COVID-19 disease

Author

Matt J. Keeling, Glen Guyver-Fletcher, Louise Dyson, Michael J. Tildesley, Edward M. Hill, and Graham F. Medley

Subjects

SARS-CoV-2, Covid, Control, Circuit-Break, Non-pharmaceutical interventions, Infectious and parasitic diseases, RC109-216

Abstract

COVID-19 in the UK has been characterised by periods of exponential growth and decline, as different non-pharmaceutical interventions (NPIs) are brought into play. During the early uncontrolled phase of the outbreak (March 2020) there was a period of prolonged exponential growth with epidemiological observations such as hospitalisation doubling every 3–4 days. The enforcement of strict lockdown measures led to a noticeable decline in all epidemic quantities that slowed during the summer as control measures were relaxed. From August 2020, infections, hospitalisations and deaths began rising once more and various NPIs were applied locally throughout the UK in response.Controlling any rise in infection is a compromise between public health and societal costs, with more stringent NPIs reducing cases but damaging the economy and restricting freedoms. Typically, NPI imposition is made in response to the epidemiological state, are of indefinite length and are often imposed at short notice, greatly increasing the negative impact. An alternative approach is to consider planned, limited duration periods of strict NPIs aiming to purposefully reduce prevalence before such emergency NPIs are required. These “precautionary breaks” may offer a means of keeping control of the epidemic, while their fixed duration and the forewarning may limit their societal impact. Here, using simple analysis and age-structured models matched to the UK SARS-CoV-2 epidemic, we investigate the action of precautionary breaks. In particular we consider their impact on the prevalence of SARS-CoV-2 infection, as well as the total number of predicted hospitalisations and deaths caused by COVID-19 disease. We find that precautionary breaks provide the biggest gains when the growth rate is low, but offer a much needed brake on increasing infection when the growth rate is higher, potentially allowing other measures to regain control.

Published

2021

14. Modelling SARS-CoV-2 transmission in a UK university setting

Author

Edward M. Hill, Benjamin D. Atkins, Matt J. Keeling, Michael J. Tildesley, and Louise Dyson

Subjects

COVID-19, SARS-CoV-2, Infectious disease model, Mathematical epidemiology, Universities, Infectious and parasitic diseases, RC109-216

Abstract

Around 40% of school leavers in the UK attend university and individual universities generally host thousands of students each academic year. Bringing together these student communities during the COVID-19 pandemic may require strong interventions to control transmission. Prior modelling analyses of SARS-CoV-2 transmission within universities using compartmental modelling approaches suggest that outbreaks are almost inevitable.We constructed a network-based model to capture the interactions of a student population in different settings (housing, social and study). For a single academic term of a representative campus-based university, we ran a susceptible–latent–infectious–recovered type epidemic process, parameterised according to available estimates for SARS-CoV-2. We investigated the impact of: adherence to (or effectiveness of) isolation and test and trace measures; room isolation of symptomatic students; and supplementary mass testing.With all adhering to test, trace and isolation measures, we found that 22% (7%–41%) of the student population could be infected during the autumn term, compared to 69% (56%–76%) when assuming zero adherence to such measures. Irrespective of the adherence to isolation measures, on average a higher proportion of students resident on-campus became infected compared to students resident off-campus. Room isolation generated minimal benefits. Regular mass testing, together with high adherence to isolation and test and trace measures, could substantially reduce the proportion infected during the term compared to having no testing.Our findings suggest SARS-CoV-2 may readily transmit in a university setting if there is limited adherence to nonpharmaceutical interventions and/or there are delays in receiving test results. Following isolation guidance and effective contact tracing curbed transmission and reduced the expected time an adhering student would spend in isolation.

Published

2021

15. SARS-CoV-2 infection in UK university students: lessons from September–December 2020 and modelling insights for future student return

Author

Jessica Enright, Edward M. Hill, Helena B. Stage, Kirsty J. Bolton, Emily J. Nixon, Emma L. Fairbanks, Maria L. Tang, Ellen Brooks-Pollock, Louise Dyson, Chris J. Budd, Rebecca B. Hoyle, Lars Schewe, Julia R. Gog, and Michael J. Tildesley

Subjects

epidemic modelling, pandemic modelling, COVID-19, SARS-CoV-2, higher education, Science

Abstract

In this paper, we present work on SARS-CoV-2 transmission in UK higher education settings using multiple approaches to assess the extent of university outbreaks, how much those outbreaks may have led to spillover in the community, and the expected effects of control measures. Firstly, we found that the distribution of outbreaks in universities in late 2020 was consistent with the expected importation of infection from arriving students. Considering outbreaks at one university, larger halls of residence posed higher risks for transmission. The dynamics of transmission from university outbreaks to wider communities is complex, and while sometimes spillover does occur, occasionally even large outbreaks do not give any detectable signal of spillover to the local population. Secondly, we explored proposed control measures for reopening and keeping open universities. We found the proposal of staggering the return of students to university residence is of limited value in terms of reducing transmission. We show that student adherence to testing and self-isolation is likely to be much more important for reducing transmission during term time. Finally, we explored strategies for testing students in the context of a more transmissible variant and found that frequent testing would be necessary to prevent a major outbreak.

Published

2021

16. A network modelling approach to assess non-pharmaceutical disease controls in a worker population: An application to SARS-CoV-2.

Author

Edward M Hill, Benjamin D Atkins, Matt J Keeling, Louise Dyson, and Michael J Tildesley

Subjects

Biology (General), QH301-705.5

Abstract

As part of a concerted pandemic response to protect public health, businesses can enact non-pharmaceutical controls to minimise exposure to pathogens in workplaces and premises open to the public. Amendments to working practices can lead to the amount, duration and/or proximity of interactions being changed, ultimately altering the dynamics of disease spread. These modifications could be specific to the type of business being operated. We use a data-driven approach to parameterise an individual-based network model for transmission of SARS-CoV-2 amongst the working population, stratified into work sectors. The network is comprised of layered contacts to consider the risk of spread in multiple encounter settings (workplaces, households, social and other). We analyse several interventions targeted towards working practices: mandating a fraction of the population to work from home; using temporally asynchronous work patterns; and introducing measures to create 'COVID-secure' workplaces. We also assess the general role of adherence to (or effectiveness of) isolation and test and trace measures and demonstrate the impact of all these interventions across a variety of relevant metrics. The progress of the epidemic can be significantly hindered by instructing a significant proportion of the workforce to work from home. Furthermore, if required to be present at the workplace, asynchronous work patterns can help to reduce infections when compared with scenarios where all workers work on the same days, particularly for longer working weeks. When assessing COVID-secure workplace measures, we found that smaller work teams and a greater reduction in transmission risk reduced the probability of large, prolonged outbreaks. Finally, following isolation guidance and engaging with contact tracing without other measures is an effective tool to curb transmission, but is highly sensitive to adherence levels. In the absence of sufficient adherence to non-pharmaceutical interventions, our results indicate a high likelihood of SARS-CoV-2 spreading widely throughout a worker population. Given the heterogeneity of demographic attributes across worker roles, in addition to the individual nature of controls such as contact tracing, we demonstrate the utility of a network model approach to investigate workplace-targeted intervention strategies and the role of test, trace and isolation in tackling disease spread.

Published

2021

17. A generation of junior faculty is at risk from the impacts of COVID-19.

Author

Tiffany M Lowe-Power, Louise Dyson, and Abigail M Polter

Subjects

Biology (General), QH301-705.5

Abstract

For junior investigators starting their independent careers, the challenges of the Coronavirus Disease 2019 (COVID-19) pandemic extend beyond lost time and are career threatening. Without intervention, academic science could lose a generation of talent.

Published

2021

18. Modelling optimal vaccination strategy for SARS-CoV-2 in the UK.

Author

Sam Moore, Edward M Hill, Louise Dyson, Michael J Tildesley, and Matt J Keeling

Subjects

Biology (General), QH301-705.5

Abstract

The COVID-19 outbreak has highlighted our vulnerability to novel infections. Faced with this threat and no effective treatment, in line with many other countries, the UK adopted enforced social distancing (lockdown) to reduce transmission-successfully reducing the reproductive number R below one. However, given the large pool of susceptible individuals that remain, complete relaxation of controls is likely to generate a substantial further outbreak. Vaccination remains the only foreseeable means of both containing the infection and returning to normal interactions and behaviour. Here, we consider the optimal targeting of vaccination within the UK, with the aim of minimising future deaths or quality adjusted life year (QALY) losses. We show that, for a range of assumptions on the action and efficacy of the vaccine, targeting older age groups first is optimal and may be sufficient to stem the epidemic if the vaccine prevents transmission as well as disease.

Published

2021

19. Predictions of COVID-19 dynamics in the UK: Short-term forecasting and analysis of potential exit strategies.

Author

Matt J Keeling, Edward M Hill, Erin E Gorsich, Bridget Penman, Glen Guyver-Fletcher, Alex Holmes, Trystan Leng, Hector McKimm, Massimiliano Tamborrino, Louise Dyson, and Michael J Tildesley

Subjects

Biology (General), QH301-705.5

Abstract

Efforts to suppress transmission of SARS-CoV-2 in the UK have seen non-pharmaceutical interventions being invoked. The most severe measures to date include all restaurants, pubs and cafes being ordered to close on 20th March, followed by a "stay at home" order on the 23rd March and the closure of all non-essential retail outlets for an indefinite period. Government agencies are presently analysing how best to develop an exit strategy from these measures and to determine how the epidemic may progress once measures are lifted. Mathematical models are currently providing short and long term forecasts regarding the future course of the COVID-19 outbreak in the UK to support evidence-based policymaking. We present a deterministic, age-structured transmission model that uses real-time data on confirmed cases requiring hospital care and mortality to provide up-to-date predictions on epidemic spread in ten regions of the UK. The model captures a range of age-dependent heterogeneities, reduced transmission from asymptomatic infections and produces a good fit to the key epidemic features over time. We simulated a suite of scenarios to assess the impact of differing approaches to relaxing social distancing measures from 7th May 2020 on the estimated number of patients requiring inpatient and critical care treatment, and deaths. With regard to future epidemic outcomes, we investigated the impact of reducing compliance, ongoing shielding of elder age groups, reapplying stringent social distancing measures using region based triggers and the role of asymptomatic transmission. We find that significant relaxation of social distancing measures from 7th May onwards can lead to a rapid resurgence of COVID-19 disease and the health system being quickly overwhelmed by a sizeable, second epidemic wave. In all considered age-shielding based strategies, we projected serious demand on critical care resources during the course of the pandemic. The reintroduction and release of strict measures on a regional basis, based on ICU bed occupancy, results in a long epidemic tail, until the second half of 2021, but ensures that the health service is protected by reintroducing social distancing measures for all individuals in a region when required. Our work confirms the effectiveness of stringent non-pharmaceutical measures in March 2020 to suppress the epidemic. It also provides strong evidence to support the need for a cautious, measured approach to relaxation of lockdown measures, to protect the most vulnerable members of society and support the health service through subduing demand on hospital beds, in particular bed occupancy in intensive care units.

Published

2021

20. Prospects for detecting early warning signals in discrete event sequence data: Application to epidemiological incidence data.

Author

Emma Southall, Michael J Tildesley, and Louise Dyson

Subjects

Biology (General), QH301-705.5

Abstract

Early warning signals (EWS) identify systems approaching a critical transition, where the system undergoes a sudden change in state. For example, monitoring changes in variance or autocorrelation offers a computationally inexpensive method which can be used in real-time to assess when an infectious disease transitions to elimination. EWS have a promising potential to not only be used to monitor infectious diseases, but also to inform control policies to aid disease elimination. Previously, potential EWS have been identified for prevalence data, however the prevalence of a disease is often not known directly. In this work we identify EWS for incidence data, the standard data type collected by the Centers for Disease Control and Prevention (CDC) or World Health Organization (WHO). We show, through several examples, that EWS calculated on simulated incidence time series data exhibit vastly different behaviours to those previously studied on prevalence data. In particular, the variance displays a decreasing trend on the approach to disease elimination, contrary to that expected from critical slowing down theory; this could lead to unreliable indicators of elimination when calculated on real-world data. We derive analytical predictions which can be generalised for many epidemiological systems, and we support our theory with simulated studies of disease incidence. Additionally, we explore EWS calculated on the rate of incidence over time, a property which can be extracted directly from incidence data. We find that although incidence might not exhibit typical critical slowing down properties before a critical transition, the rate of incidence does, presenting a promising new data type for the application of statistical indicators.

Published

2020

21. Measuring and modelling the effects of systematic non-adherence to mass drug administration

Author

Louise Dyson, Wilma A. Stolk, Sam H. Farrell, and T. Déirdre Hollingsworth

Subjects

Neglected tropical diseases, Coverage, Systematic non-compliance, Systematic, non-adherence, Modelling, Infectious and parasitic diseases, RC109-216

Abstract

It is well understood that the success or failure of a mass drug administration campaign critically depends on the level of coverage achieved. To that end coverage levels are often closely scrutinised during campaigns and the response to underperforming campaigns is to attempt to improve coverage. Modelling work has indicated, however, that the quality of the coverage achieved may also have a significant impact on the outcome. If the coverage achieved is likely to miss similar people every round then this can have a serious detrimental effect on the campaign outcome. We begin by reviewing the current modelling descriptions of this effect and introduce a new modelling framework that can be used to simulate a given level of systematic non-adherence. We formalise the likelihood that people may miss several rounds of treatment using the correlation in the attendance of different rounds. Using two very simplified models of the infection of helminths and non-helminths, respectively, we demonstrate that the modelling description used and the correlation included between treatment rounds can have a profound effect on the time to elimination of disease in a population. It is therefore clear that more detailed coverage data is required to accurately predict the time to disease elimination. We review published coverage data in which individuals are asked how many previous rounds they have attended, and show how this information may be used to assess the level of systematic non-adherence. We note that while the coverages in the data found range from 40.5% to 95.5%, still the correlations found lie in a fairly narrow range (between 0.2806 and 0.5351). This indicates that the level of systematic non-adherence may be similar even in data from different years, countries, diseases and administered drugs.

Published

2017

22. Insights from quantitative and mathematical modelling on the proposed 2030 goals for Yaws [version 1; peer review: 2 approved]

Author

Louise Dyson, Eric Q. Mooring, Alex Holmes, Michael J. Tildesley, and Michael Marks

Subjects

Medicine

Abstract

The World Health Organization is currently developing 2030 goals for neglected tropical diseases (NTDs). In these, yaws has been targeted for eradication by 2030, with 50% of member states certified free of yaws transmission by 2023. Here we summarise the yaws modelling literature and discuss the proposed goal and strategy. The current Morges strategy involves rounds of Total Community Treatment (TCT), in which all members of the community are treated, and Total Targeted Treatment (TTT), treating active cases and their contacts. However, modelling and empirical work suggest that latent infections are often not found in the same household as active cases, reducing the utility of household-based contact tracing for a TTT strategy. Economic modelling has also discovered uncertainty in the cost of eradication, requiring further data to give greater information. We also note the need for improved active surveillance in previously endemic countries, in order to plan future intervention efforts and ensure global eradication.

Published

2019

23. Quantitative analyses and modelling to support achievement of the 2020 goals for nine neglected tropical diseases

Author

T. Déirdre Hollingsworth, Emily R. Adams, Roy M. Anderson, Katherine Atkins, Sarah Bartsch, María-Gloria Basáñez, Matthew Behrend, David J. Blok, Lloyd A. C. Chapman, Luc Coffeng, Orin Courtenay, Ron E. Crump, Sake J. de Vlas, Andy Dobson, Louise Dyson, Hajnal Farkas, Alison P. Galvani, Manoj Gambhir, David Gurarie, Michael A. Irvine, Sarah Jervis, Matt J. Keeling, Louise Kelly-Hope, Charles King, Bruce Y. Lee, Epke A. Le Rutte, Thomas M. Lietman, Martial Ndeffo-Mbah, Graham F. Medley, Edwin Michael, Abhishek Pandey, Jennifer K. Peterson, Amy Pinsent, Travis C. Porco, Jan Hendrik Richardus, Lisa Reimer, Kat S. Rock, Brajendra K. Singh, Wilma Stolk, Subramanian Swaminathan, Steve J. Torr, Jeffrey Townsend, James Truscott, Martin Walker, Alexandra Zoueva, and NTD Modelling Consortium

Subjects

Modelling, Elimination, Neglected tropical diseases, Transmission, Chagas disease, Visceral leishmaniasis, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Quantitative analysis and mathematical models are useful tools in informing strategies to control or eliminate disease. Currently, there is an urgent need to develop these tools to inform policy to achieve the 2020 goals for neglected tropical diseases (NTDs). In this paper we give an overview of a collection of novel model-based analyses which aim to address key questions on the dynamics of transmission and control of nine NTDs: Chagas disease, visceral leishmaniasis, human African trypanosomiasis, leprosy, soil-transmitted helminths, schistosomiasis, lymphatic filariasis, onchocerciasis and trachoma. Several common themes resonate throughout these analyses, including: the importance of epidemiological setting on the success of interventions; targeting groups who are at highest risk of infection or re-infection; and reaching populations who are not accessing interventions and may act as a reservoir for infection,. The results also highlight the challenge of maintaining elimination ‘as a public health problem’ when true elimination is not reached. The models elucidate the factors that may be contributing most to persistence of disease and discuss the requirements for eventually achieving true elimination, if that is possible. Overall this collection presents new analyses to inform current control initiatives. These papers form a base from which further development of the models and more rigorous validation against a variety of datasets can help to give more detailed advice. At the moment, the models’ predictions are being considered as the world prepares for a final push towards control or elimination of neglected tropical diseases by 2020.

Published

2015

24. Quantification of the natural history of visceral leishmaniasis and consequences for control

Author

Lloyd A C Chapman, Louise Dyson, Orin Courtenay, Rajib Chowdhury, Caryn Bern, Graham F. Medley, and T. Deirdre Hollingsworth

Subjects

Visceral leishmaniasis, Natural history, Control, Diagnostics, Multi-state Markov model, Indian sub-continent, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background Visceral leishmaniasis has been targeted for elimination as a public health problem (less than 1 case per 10,000 people per year) in the Indian sub-continent by 2017. However, there is still a high degree of uncertainty about the natural history of the disease, in particular about the duration of asymptomatic infection and the proportion of asymptomatically infected individuals that develop clinical visceral leishmaniasis. Quantifying these aspects of the disease is key for guiding efforts to eliminate visceral leishmaniasis and maintaining elimination once it is reached. Methods Data from a detailed epidemiological study in Bangladesh in 2002–2004 was analysed to estimate key epidemiological parameters. The role of diagnostics in determining the probability and rate of progression to clinical disease was estimated by fitting Cox proportional hazards models. A multi-state Markov model of the natural history of visceral leishmaniasis was fitted to the data to estimate the asymptomatic infection period and the proportion of asymptomatic individuals going on to develop clinical symptoms. Results At the time of the study, individuals were taking several months to be diagnosed with visceral leishmaniasis, leading to many opportunities for ongoing transmission. The probability of progression to clinical disease was strongly associated with initial seropositivity and even more strongly with seroconversion, with most clinical symptoms developing within a year. The estimated average durations of asymptomatic infection and symptomatic infection for our model of the natural history are 147 days (95 % CI 130–166) and 140 days (95 % CI 123–160), respectively, and are significantly longer than previously reported estimates. We estimate from the data that 14.7 % (95 % CI 12.6-20.0 %) of asymptomatic individuals develop clinical symptoms—a greater proportion than previously estimated. Conclusions Extended periods of asymptomatic infection could be important for visceral leishmaniasis transmission, but this depends critically on the relative infectivity of asymptomatic and symptomatic individuals to sandflies. These estimates could be informed by similar analysis of other datasets. Our results highlight the importance of reducing times from onset of symptoms to diagnosis and treatment to reduce opportunities for transmission.

Published

2015

25. Staged Models for Interdisciplinary Research.

Author

Luis F Lafuerza, Louise Dyson, Bruce Edmonds, and Alan J McKane

Subjects

Medicine, Science

Abstract

Modellers of complex biological or social systems are often faced with an invidious choice: to use simple models with few mechanisms that can be fully analysed, or to construct complicated models that include all the features which are thought relevant. The former ensures rigour, the latter relevance. We discuss a method that combines these two approaches, beginning with a complex model and then modelling the complicated model with simpler models. The resulting "chain" of models ensures some rigour and relevance. We illustrate this process on a complex model of voting intentions, constructing a reduced model which agrees well with the predictions of the full model. Experiments with variations of the simpler model yield additional insights which are hidden by the complexity of the full model. This approach facilitated collaboration between social scientists and physicists-the complex model was specified based on the social science literature, and the simpler model constrained to agree (in core aspects) with the complicated model.

Published

2016

26. A retrospective assessment of forecasting the peak of the SARS-CoV-2 Omicron BA.1 wave in England.

Author

Matt J. Keeling and Louise Dyson

Published

2024

27. Public perceptions and interactions with UK COVID-19 Test, Trace and Isolate policies, and implications for pandemic infectious disease modelling [version 1; peer review: awaiting peer review]

Author

Guy C. Marshall, Rigina Skeva, Caroline Jay, Miguel E. P. Silva, Martyn Fyles, Thomas House, Emma L. Davis, Li Pi, Graham F. Medley, Billy J. Quilty, Louise Dyson, Lucy Yardley, and Elizabeth Fearon

Subjects

Research Article, Articles, COVID-19, SARS-CoV-2, infectious disease, public health, mathematical modelling, qualitative research, public engagement, pandemic preparedness

Abstract

Background The efforts to contain SARS-CoV-2 and reduce the impact of the COVID-19 pandemic have been supported by Test, Trace and Isolate (TTI) systems in many settings, including the United Kingdom. Mathematical models of transmission and TTI interventions, used to inform design and policy choices, make assumptions about the public’s behaviour in the context of a rapidly unfolding and changeable emergency. This study investigates public perceptions and interactions with UK TTI policy in July 2021, assesses them against how TTI processes are conceptualised and represented in models, and then interprets the findings with modellers who have been contributing evidence to TTI policy. Methods 20 members of the public recruited via social media were interviewed for one hour about their perceptions and interactions with the UK TTI system. Thematic analysis identified key themes, which were then presented back to a workshop of pandemic infectious disease modellers who assessed these findings against assumptions made in TTI intervention modelling. Workshop members co-drafted this report. Results Themes included education about SARS-CoV-2, perceived risks, trust, mental health and practical concerns. Findings covered testing practices, including the uses of and trust in different types of testing, and the challenges of testing and isolating faced by different demographic groups. This information was judged as consequential to the modelling process, from guiding the selection of research questions, influencing choice of model structure, informing parameter ranges and validating or challenging assumptions, to highlighting where model assumptions are reasonable or where their poor reflection of practice might lead to uninformative results. Conclusions We conclude that deeper engagement with members of the public should be integrated at regular stages of public health intervention modelling.

Published

2022

28. Retrospectively modeling the effects of increased global vaccine sharing on the COVID-19 pandemic

Author

Sam Moore, Edward M. Hill, Louise Dyson, Michael J. Tildesley, and Matt J. Keeling

Subjects

General Medicine, General Biochemistry, Genetics and Molecular Biology

Abstract

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic has caused considerable morbidity and mortality worldwide. The protection provided by vaccines and booster doses offered a method of mitigating severe clinical outcomes and mortality. However, by the end of 2021, the global distribution of vaccines was highly heterogeneous, with some countries gaining over 90% coverage in adults, whereas others reached less than 2%. In this study, we used an age-structured model of SARS-CoV-2 dynamics, matched to national data from 152 countries in 2021, to investigate the global impact of different potential vaccine sharing protocols that attempted to address this inequity. We quantified the effects of implemented vaccine rollout strategies on the spread of SARS-CoV-2, the subsequent global burden of disease and the emergence of novel variants. We found that greater vaccine sharing would have lowered the total global burden of disease, and any associated increases in infections in previously vaccine-rich countries could have been mitigated by reduced relaxation of non-pharmaceutical interventions. Our results reinforce the health message, pertinent to future pandemics, that vaccine distribution proportional to wealth, rather than to need, may be detrimental to all.

Published

2022

29. Author Correction: Retrospectively modeling the effects of increased global vaccine sharing on the COVID-19 pandemic

Author

Sam Moore, Edward M. Hill, Louise Dyson, Michael J. Tildesley, and Matt J. Keeling

Subjects

General Medicine, General Biochemistry, Genetics and Molecular Biology

Published

2023

30. Public perceptions and interactions with UK COVID-19 Test, Trace and Isolate policies, and implications for pandemic infectious disease modelling

Author

Guy C. Marshall, Rigina Skeva, Caroline Jay, Miguel E. P. Silva, Martyn Fyles, Thomas House, Emma L. Davis, Li Pi, Graham F. Medley, Billy J. Quilty, Louise Dyson, Lucy Yardley, and Elizabeth Fearon

Subjects

General Immunology and Microbiology, SARS-CoV-2, infectious disease, covid 19, public health, Covid19, General Medicine, General Biochemistry, Genetics and Molecular Biology, public engagement, pandemic preparedness, Physical and Mental Health, mathematical modelling, General Pharmacology, Toxicology and Pharmaceutics, qualitative research

Abstract

Background The efforts to contain SARS-CoV-2 and reduce the impact of the COVID-19 pandemic have been supported by Test, Trace and Isolate (TTI) systems in many settings, including the United Kingdom. Mathematical models of transmission and TTI interventions, used to inform design and policy choices, make assumptions about the public’s behaviour in the context of a rapidly unfolding and changeable emergency. This study investigates public perceptions and interactions with UK TTI policy in July 2021, assesses them against how TTI processes are conceptualised and represented in models, and then interprets the findings with modellers who have been contributing evidence to TTI policy. Methods 20 members of the public recruited via social media were interviewed for one hour about their perceptions and interactions with the UK TTI system. Thematic analysis identified key themes, which were then presented back to a workshop of pandemic infectious disease modellers who assessed these findings against assumptions made in TTI intervention modelling. Workshop members co-drafted this report. Results Themes included education about SARS-CoV-2, perceived risks, trust, mental health and practical concerns. Findings covered testing practices, including the uses of and trust in different types of testing, and the challenges of testing and isolating faced by different demographic groups. This information was judged as consequential to the modelling process, from guiding the selection of research questions, influencing choice of model structure, informing parameter ranges and validating or challenging assumptions, to highlighting where model assumptions are reasonable or where their poor reflection of practice might lead to uninformative results. Conclusions We conclude that deeper engagement with members of the public should be integrated at regular stages of public health intervention modelling.

Published

2022

31. Staged Models for Interdisciplinary Research.

Author

Luis F. Lafuerza, Louise Dyson, Bruce Edmonds, and Alan J. McKane

Published

2016

32. How early can an upcoming critical transition be detected?

Author

Emma Southall, Michael J Tildesley, and Louise Dyson

Abstract

Numerous studies have suggested the use of early warning signals (EWSs) of critical transitions to overcome challenges of identifying tipping points in complex natural systems. However, the real-time application of EWSs has often been overlooked; many studies show the presence of EWSs but do not detect when the trend becomes significant. Knowing if the signal can be detected early enough is of critical importance for the applicability of EWSs. Detection methods which present this analysis are sparse and are often developed anew for each individual study. Here, we provide a summary and validation of a range of currently available detection methods developed from EWSs. We include an additional constraint, which requires multiple time-series points to satisfy the algorithms’ conditions before a detection of an approaching critical transition can be flagged. We apply this procedure to a simulated study of an infectious disease system undergoing disease elimination. For each detection algorithm we select the hyper-parameter which minimises classification errors using receiver operating characteristic (ROC) analysis. We consider the effect of time-series length on these results, finding that all algorithms become less accurate as the amount of data decreases. We compare EWS detection methods with alternate algorithms found from the change-point analysis literature and assess the suitability of using change-point analysis to detect abrupt changes in a system’s steady state.

Published

2022

33. Modelling results on the impact of COVID-19 testing in schools

Author

Louise Dyson

Subjects

Infectious Diseases, COVID-19 Testing, Schools, SARS-CoV-2, COVID-19, Humans

Published

2022

34. Approximating steady state distributions for household structured epidemic models

Author

Tildesley Mj, Louise Dyson, and Alexander Holmes

Subjects

Statistics and Probability, Mathematical optimization, Steady state (electronics), General Immunology and Microbiology, Computer science, Applied Mathematics, Structure (category theory), General Medicine, Parameter space, System of linear equations, General Biochemistry, Genetics and Molecular Biology, Moment closure, Transmission (telecommunications), Modeling and Simulation, Master equation, Humans, Fokker–Planck equation, General Agricultural and Biological Sciences, Epidemics, QA, RA

Abstract

Household-structured infectious disease models consider the increased transmission potential between ind[a,]ividuals of the same household when compared with two individuals in different households. Accounting for these heterogeneities in transmission enables control measures to be more effectively planned. Ideally, pre-control data may be used to fit such a household-structured model at an endemic steady state, before making dynamic forward-predictions under different proposed strategies. However, this requires the accurate calculation of the steady states for the full dynamic model. We observe that steady state SIS dynamics with household structure cannot necessarily be described by the master equation for a single household, instead requiring consideration of the full system. However, solving the full system of equations becomes increasingly computationally intensive, particularly for higher-dimensional models. We compare two approximations to the full system: the single household master equation; and a proposed alternative method, using the Fokker-Planck equation. Moment closure is another commonly used method, but for more complicated systems, the equations quickly become unwieldy and very difficult to derive. In comparison, using the master equation for a single household is easily implementable, however it can be quite inaccurate. In this paper we compare these methods in terms of accuracy and ease of implementation. We find that there are regions of parameter space in which each method outperforms the other, and that these regions of parameter space can be characterised by the infection prevalence, or by the correlation between household states.\ud \ud

Published

2022

35. How modelling can help steer the course set by the World Health Organization 2021-2030 roadmap on neglected tropical diseases

Author

Jessica Clark, Wilma A. Stolk, María-Gloria Basáñez, Luc E. Coffeng, Zulma M. Cucunubá, Matthew A. Dixon, Louise Dyson, Katie Hampson, Michael Marks, Graham F. Medley, Timothy M. Pollington, Joaquin M. Prada, Kat S. Rock, Henrik Salje, Jaspreet Toor, T. Déirdre Hollingsworth, and Public Health

Subjects

Immunology and Microbiology (miscellaneous), SDG 3 - Good Health and Well-being, Health Policy, Public Health, Environmental and Occupational Health, Medicine (miscellaneous), Biochemistry, Genetics and Molecular Biology (miscellaneous)

Abstract

The World Health Organization recently launched its 2021-2030 roadmap, Ending the Neglect to Attain the Sustainable Development Goals, an updated call to arms to end the suffering caused by neglected tropical diseases. Modelling and quantitative analyses played a significant role in forming these latest goals. In this collection, we discuss the insights, the resulting recommendations and identified challenges of public health modelling for 13 of the target diseases: Chagas disease, dengue, gambiense human African trypanosomiasis (gHAT), lymphatic filariasis (LF), onchocerciasis, rabies, scabies, schistosomiasis, soil-transmitted helminthiases (STH), Taenia solium taeniasis/ cysticercosis, trachoma, visceral leishmaniasis (VL) and yaws. This piece reflects the three cross-cutting themes identified across the collection, regarding the contribution that modelling can make to timelines, programme design, drug development and clinical trials.

Published

2022

36. The impacts of increased global vaccine sharing on the COVID-19 pandemic; a retrospective modelling study

Author

Sam Moore, Edward M. Hill, Louise Dyson, Michael J. Tildesley, and Matt J. Keeling

Abstract

SummaryBackgroundThe SARS-CoV-2 pandemic has generated considerable morbidity and mortality world-wide. While the protection offered by vaccines (and booster doses) offers a method of mitigating the worst effects, by the end of 2021 the distribution of vaccine was highly heterogeneous with some countries achieving over 90% coverage in adults by the end of 2021, while others have less than 2%. In part, this is due to the availability of sufficient vaccine, although vaccine hesitancy also plays a role.MethodsWe use an age-structured model of SARS-CoV-2 dynamics, matched to national data from 152 countries, to investigate the global impact of different vaccine sharing protocols during 2021. We assume a direct relationship between the emergence of variants with increased transmissibility and the cumulative amount of global infection, such that lower global prevalence leads to a lower reproductive number within each country. We compare five vaccine sharing scenarios, from the current situation, through sharing once a particular within-country threshold is reached (e.g. all over 40s have received 2 doses), to full sharing where all countries achieve equal age-dependent vaccine deployment.FindingsCompared to the observed distribution of vaccine uptake, we estimate full vaccine sharing would have generated a 1.5% (PI -0.1 - 4.5%) reduction in infections and a 11.3% (PI 0.6 - 23.2%) reduction in mortality globally by January 2022. The greatest benefit of vaccine sharing would have been experienced by low and middle income countries, who see an average 5.2% (PI 2.5% - 10.4%) infection reduction and 26.8% (PI 24.1% - 31.3%) mortality reduction. Many high income countries, that have had high vaccine uptake (most notably Canada, Chile, UK and USA), suffer increased infections and mortality under most of the sharing protocols investigated, assuming no other counter measures had been taken. However, if reductions in vaccine supply in these countries had been offset by prolonged use of non-pharmaceutical intervention measures, we predict far greater reductions in global infection and mortality of 64.5% (PI 62.6% - 65.4%) and 62.8% (PI 44.0% - 76.3%), respectively.InterpretationBy itself, our results suggest that although more equitable vaccine distribution would have had limited impact on overall infection numbers, vaccine sharing would have substantially reduced global mortality by providing earlier protection of the most vulnerable. If increased vaccine sharing from high income nations had been combined with slower easing of non pharmaceutical interventions to compensate for this, a large reduction in both infection and mortality globally would be expected, confounded by a lower risk of new variants arising.

Published

2022

37. Bayesian Estimation of real-time Epidemic Growth Rates using Gaussian Processes: local dynamics of SARS-CoV-2 in England

Author

Laura M Guzmán-Rincón, Edward M Hill, Louise Dyson, Michael J Tildesley, and Matt J Keeling

Abstract

Quantitative assessments of the recent state of an epidemic and short-term projections into the near future are key public health tools that have substantial policy impacts, helping to determine if existing control measures are sufficient or need to be strengthened. Key to these quantitative assessments is the ability to rapidly and robustly measure the speed with which the epidemic is growing or decaying. Frequently, epidemiological trends are addressed in terms of the (time-varying) reproductive numberR. Here, we take a more parsimonious approach and calculate the exponential growth rate,r, using a Bayesian hierarchical model to fit a Gaussian process to the epidemiological data. We show how the method can be employed when only case data from positive tests are available, and the improvement gained by including the total number of tests as a measure of heterogeneous testing effort. Although the methods are generic, we apply them to SARS-CoV-2 cases and testing in England, making use of the available high-resolution spatio-temporal data to determine long-term patterns of national growth, highlight regional growth and spatial heterogeneity.

Published

2022

38. Simplification and analysis of a model of social interaction in voting.

Author

Luis F. Lafuerza, Louise Dyson, Bruce Edmonds, and Alan J. McKane

Published

2015

39. Short-term Projections based on Early Omicron Variant Dynamics in England

Author

Matt J. Keeling, Ellen Brooks-Pollock, Rob Challen, Leon Danon, Louise Dyson, Julia R. Gog, Laura Guzmán Rincón, Edward M. Hill, Lorenzo Pellis, Jonathan M. Read, and Michael J. Tildesley

Abstract

Throughout the ongoing COVID-19 pandemic, the worldwide transmission and replication of SARS-COV-2, the causative agent of COVID-19 disease, has resulted in the opportunity for multiple mutations to occur that may alter the virus transmission characteristics, the effectiveness of vaccines and the severity of disease upon infection. The Omicron variant (B.1.1.529) was first reported to the WHO by South Africa on 24 November 2021 and was declared a variant of concern by the WHO on 26 November 2021. The variant was first detected in the UK on 27 November 2021 and has since been reported in a number of countries globally where it is frequently associated with rapid increase in cases. Here we present analyses of UK data showing the earliest signatures of the Omicron variant and mathematical modelling that uses the UK data to simulate the potential impact of this variant in the UK. In order to account for the uncertainty in transmission advantage, vaccine escape and severity at the time of writing, we carry out a sensitivity analysis to assess the impact of these variant characteristics on future risk.

Published

2021

40. Waning, Boosting and a Path to Endemicity for SARS-CoV-2

Author

Louise Dyson, Sam Moore, Michael J. Tildesley, Amy Thomas, Edward M. Hill, Matthew James Keeling, and Robin N Thompson

Subjects

Vaccination, medicine.medical_specialty, Boosting (doping), Booster (rocketry), business.industry, Public health, Environmental health, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Medicine, Booster dose, business, Vaccine efficacy, Herd immunity

Abstract

In many countries, an extensive vaccination programme has substantially reduced the public-health impact of SARS-CoV-2, limiting the number of hospital admissions and deaths compared to an unmitigated epidemic. Ensuring a low-risk transition from the current situation to one in which SARS-CoV-2 is endemic requires maintenance of high levels of population immunity. The observed waning of vaccine efficacy over time suggests that booster doses may be required to maintain population immunity especially in the most vulnerable groups. Here, using data and models for England, we consider the dynamics of COVID-19 over a two-year time-frame, and the role that booster vaccinations can play in mitigating the worst effects. We find that boosters are necessary to suppress the imminent wave of infections that would be generated by waning vaccine efficacy. Projecting further into the future, the optimal deployment of boosters is highly sensitive to their long-term action. If protection from boosters wanes slowly (akin to protection following infection) then a single booster dose to the over 50s may be all that is needed over the next two-years. However, if protection wanes more rapidly (akin to protection following second dose vaccination) then annual or even biannual boosters are required to limit subsequent epidemic peaks an reduce the pressure on public health services.

Published

2021

41. The risk of SARS-CoV-2 outbreaks in low prevalence settings following the removal of travel restrictions

Author

Robin N Thompson, Louise Dyson, Rahil Sachak-Patwa, and Helen M. Byrne

Subjects

education.field_of_study, medicine.medical_specialty, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Public health, Population, Psychological intervention, Outbreak, Herd immunity, law.invention, Vaccination, Geography, Transmission (mechanics), law, RA0421, Environmental health, medicine, Medicine, education

Abstract

Countries around the world have introduced travel restrictions to reduce SARS-CoV-2 transmission. As vaccines are gradually rolled out, attention has turned to when travel restrictions and other non-pharmaceutical interventions (NPIs) can be relaxed. Using SARS-CoV-2 as a case study, we develop a mathematical branching process model to assess the risk that, following the removal of NPIs, cases arriving in low prevalence settings initiate a local outbreak. Our model accounts for changes in background population immunity due to vaccination. We consider two locations with low prevalence in which the vaccine rollout has progressed quickly – specifically, the Isle of Man (a British crown dependency in the Irish Sea) and the country of Israel. We show that the outbreak risk is unlikely to be eliminated completely when travel restrictions and other NPIs are removed. This general result is the most important finding of this study, rather than exact quantitative outbreak risk estimates in different locations. It holds even once vaccine programmes are completed. Key factors underlying this result are the potential for transmission even following vaccination, incomplete vaccine uptake, and the recent emergence of SARS-CoV-2 variants with increased transmissibility. Combined, the factors described above suggest that, when travel restrictions are relaxed, it may still be necessary to implement surveillance of incoming passengers to identify infected individuals quickly. This measure, as well as tracing and testing (and/or isolating) contacts of detected infected passengers, remains useful to suppress potential outbreaks while global case numbers are high. The effectiveness of public health measures against COVID-19 has varied between countries, with some experiencing many infections and others containing transmission successfully. As vaccines are deployed, an important challenge is deciding when to relax measures. Here, we consider locations with few cases, and investigate whether vaccination can ever eliminate the risk of COVID-19 outbreaks completely, allowing measures to be removed risk-free. Using a mathematical model, we demonstrate that there is still a risk that imported cases initiate outbreaks when measures are removed, even if most of the population is fully vaccinated. This highlights the need for continued vigilance in low prevalence settings to prevent imported cases leading to local transmission. Until case numbers are reduced globally, so that SARS-CoV-2 spread between countries is less likely, the risk of outbreaks in low prevalence settings will remain. Sachak-Patwa et al. estimate the risk of SARS-CoV-2 outbreaks in low prevalence settings following the removal of travel restrictions and other non-pharmaceutical interventions, with the Isle of Man and Israel as case studies. Using a branching process mathematical model, the authors show that even after a large proportion of the population is vaccinated, there remains a risk of local outbreaks from imported cases.

Published

2021

42. Exploring the role of the potential surface in the behaviour of early warning signals

Author

Andrew Nugent, Emma Southall, and Louise Dyson

Subjects

Statistics and Probability, Stochastic Processes, General Immunology and Microbiology, Incidence, Applied Mathematics, General Medicine, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Modeling and Simulation, QA, Epidemics, General Agricultural and Biological Sciences, RA, RC, Forecasting

Abstract

The theory of critical slowing down states that a system displays increasing relaxation times as it approaches a critical transition. These changes can be seen in statistics generated from timeseries data, which can be used as early warning signals of a transition. Such early warning signals would be of value for emerging infectious diseases or to understand when an endemic disease is close to elimination. However, in applications to a variety of epidemiological models there is frequent disagreement with the general theory of critical slowing down, with some indicators performing well on prevalence data but not when applied to incidence data. Furthermore, the alternative theory of critical speeding up predicts contradictory behaviour of early warning signals prior to some stochastic transitions. To investigate the possibility of observing critical speeding up in epidemiological models we characterise the behaviour of common early warning signals in terms of a system’s potential surface and noise around a quasi-steady state. We then describe a method to obtain these key features from timeseries data, taking as a case study a version of the SIS model, adapted to demonstrate either critical slowing down or critical speeding up. We show this method accurately reproduces the analytic potential surface and diffusion function, and that these results can be used to determine the behaviour of early warning signals and correctly identify signs of both critical slowing down and critical speeding up.

Published

2022

43. Early warning signals of infectious disease transitions: a review

Author

Louise Dyson, Emma Southall, Tobias S. Brett, and Michael J. Tildesley

Subjects

critical transitions, Warning system, Computer science, Biomedical Engineering, Biophysics, Bioengineering, critical slowing down, Biochemistry, Communicable Diseases, Biomaterials, Critical transition, Risk analysis (engineering), disease emergence, Infectious disease (medical specialty), Complex vector, time-series signals, early warning signals, Humans, disease elimination, Disease Elimination, Epidemics, Review Articles, Biotechnology, Forecasting

Abstract

Early warning signals (EWSs) are a group of statistical time-series signals which could be used to anticipate a critical transition before it is reached. EWSs are model-independent methods that have grown in popularity to support evidence of disease emergence and disease elimination. Theoretical work has demonstrated their capability of detecting disease transitions in simple epidemic models, where elimination is reached through vaccination, to more complex vector transmission, age-structured and metapopulation models. However, the exact time evolution of EWSs depends on the transition; here we review the literature to provide guidance on what trends to expect and when. Recent advances include methods which detect when an EWS becomes significant; the earlier an upcoming disease transition is detected, the more valuable an EWS will be in practice. We suggest that future work should firstly validate detection methods with synthetic and historical datasets, before addressing their performance with real-time data which is accruing. A major challenge to overcome for the use of EWSs with disease transitions is to maintain the accuracy of EWSs in data-poor settings. We demonstrate how EWSs behave on reported cases for pertussis in the USA, to highlight some limitations when detecting disease transitions with real-world data.

Published

2021

44. Modelling SARS-CoV-2 transmission in a UK university setting

Author

Louise Dyson, Edward M. Hill, Michael J. Tildesley, Matthew James Keeling, and Benjamin D. Atkins

Subjects

Isolation (health care), Universities, Epidemiology, 030231 tropical medicine, education, Psychological intervention, Infectious and parasitic diseases, RC109-216, Microbiology, Article, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Virology, Pandemic, Humans, Medicine, 030212 general & internal medicine, Pandemics, Academic year, Mathematical epidemiology, business.industry, SARS-CoV-2, Public Health, Environmental and Occupational Health, COVID-19, Academic term, United Kingdom, Term (time), Test (assessment), Infectious Diseases, Transmission (mechanics), Parasitology, Infectious disease model, business, RA, Contact tracing, Demography

Abstract

Background Around 40% of school leavers in the UK attend university and individual universities generally host thousands of students each academic year. Bringing together these student communities during the COVID-19 pandemic may require strong interventions to control transmission. Prior modelling analysis of SARS-CoV-2 transmission within universities that use compartmental modelling approaches suggest that outbreaks are almost inevitable. Methods We constructed a network-based model to capture the interactions of a student population in different settings (housing, social and study). For a single academic term of a representative campus-based university, we ran a susceptible-latent-infectious-recovered type epidemic process, parameterised according to available estimates for SARS-CoV-2. We investigated the impact of: adherence to (or effectiveness of) isolation and test and trace measures; single-room isolation of cases; supplementary mass testing. Results Incorporating uncertainty in the asymptomatic fraction of cases and their associated infectivity, in the absence of interventions our model estimated that 69% (55% - 75%) of the student population could be infected during the autumn term. With full adherence to test, trace and isolate measures, we found lower cumulative infection estimates of 19% (5% - 39%). Irrespective of the adherence to isolation measures, on average a higher proportion of students resident on-campus became infected than off-campus. Room isolation generated minimal benefits. A one-off instance of mass testing would not drastically reduce the term-long case load, though if performed a couple of weeks before the end-of-term it could reduce the expected end-of-term prevalence. Regular testing, together with high adherence to isolation, test and trace measures, could reduce the proportion infected during the term by more than 50% compared to having no mass testing. Conclusions Our findings suggest SARS-CoV-2 may readily transmit in a university setting if there is limited adherence to nonpharmaceutical interventions and/or there are delays in receiving test results. Following isolation guidance and effective contact tracing curbed transmission and reduced the expected time an adhering student would spend in isolation. Additionally, widespread adherence throughout the term suppresses the amount of unwitting asymptomatic transmission to family and community members in the students’ domicile regions after term ends.

Published

2021

45. SARS-CoV-2 infection in UK university students: lessons from September-December 2020 and modelling insights for future student return

Author

Julia R. Gog, Louise Dyson, Jessica Enright, Kirsty J. Bolton, Lars Schewe, Edward M. Hill, Rebecca B. Hoyle, Michael J. Tildesley, Helena B. Stage, Ellen Brooks-Pollock, Emily Nixon, Emma L. Fairbanks, Maria L Tang, Chris Budd, Tang, Maria Lan [0000-0002-9671-8302], Gog, Julia [0000-0003-1240-7214], Apollo - University of Cambridge Repository, Enright, Jessica [0000-0002-0266-3292], Hill, Edward M. [0000-0002-2992-2004], Stage, Helena B. [0000-0001-9938-8452], Bolton, Kirsty J. [0000-0003-0487-4701], Nixon, Emily J. [0000-0002-1626-9296], Fairbanks, Emma L. [0000-0002-1598-962X], Tang, Maria L. [0000-0002-9671-8302], Brooks-Pollock, Ellen [0000-0002-5984-4932], Dyson, Louise [0000-0001-9788-4858], Budd, Chris J. [0000-0003-4536-1662], Hoyle, Rebecca B. [0000-0002-1645-1071], Schewe, Lars [0000-0002-3778-262X], Gog, Julia R. [0000-0003-1240-7214], and Tildesley, Michael J. [0000-0002-6875-7232]

Subjects

LB2300, Higher education, Science, education, Distribution (economics), Context (language use), epidemic modelling, law.invention, Spillover effect, law, Multidisciplinary, business.industry, SARS-CoV-2, Outbreak, COVID-19, Science, society and policy, Geography, Transmission (mechanics), Work (electrical), higher education, pandemic modelling, Residence, Demographic economics, business, RA

Abstract

Funder: Isaac Newton Institute for Mathematical Sciences; Id: http://dx.doi.org/10.13039/501100005347, Funder: Wellcome Trust; Id: http://dx.doi.org/10.13039/100004440, Funder: Medical Research Council; Id: http://dx.doi.org/10.13039/501100000265, Funder: UKRI, Funder: University of Nottingham; Id: http://dx.doi.org/10.13039/501100000837, In this paper, we present work on SARS-CoV-2 transmission in UK higher education settings using multiple approaches to assess the extent of university outbreaks, how much those outbreaks may have led to spillover in the community, and the expected effects of control measures. Firstly, we found that the distribution of outbreaks in universities in late 2020 was consistent with the expected importation of infection from arriving students. Considering outbreaks at one university, larger halls of residence posed higher risks for transmission. The dynamics of transmission from university outbreaks to wider communities is complex, and while sometimes spillover does occur, occasionally even large outbreaks do not give any detectable signal of spillover to the local population. Secondly, we explored proposed control measures for reopening and keeping open universities. We found the proposal of staggering the return of students to university residence is of limited value in terms of reducing transmission. We show that student adherence to testing and self-isolation is likely to be much more important for reducing transmission during term time. Finally, we explored strategies for testing students in the context of a more transmissible variant and found that frequent testing would be necessary to prevent a major outbreak.

Published

2021

46. Quantifying within-school SARS-CoV-2 transmission and the impact of lateral flow testing in secondary schools in England

Author

Michael J. Tildesley, Emma Southall, Edward M. Hill, Trystan Leng, Matthew James Keeling, Louise Dyson, Alexander Holmes, and Robin N Thompson

Subjects

Flow Testing, Potential impact, 2019-20 coronavirus outbreak, Transmission (mechanics), Geography, Isolation (health care), Coronavirus disease 2019 (COVID-19), law, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), education, Demography, law.invention

Abstract

BackgroundTo control within-school SARS-CoV-2 transmission in England, secondary school pupils have been encouraged to participate in twice weekly mass testing via lateral flow device tests (LFTs) from 8th March 2021, to complement an isolation of close contacts policy in place since 31st August 2020. Strategies involving the isolation of close contacts can lead to high levels of absences, negatively impacting pupils.MethodsWe fit a stochastic individual-based model of secondary schools to both community swab testing data and secondary school absences data. By simulating epidemics in secondary schools from 31st August 2020 until 21st May 2021, we quantify within-school transmission of SARS-CoV-2 in secondary schools in England, the impact of twice weekly mass testing on within-school transmission, and the potential impact of alternative strategies to the isolation of close contacts in reducing pupil absences.FindingsThe within-school reproduction number, Rschool, has remained below 1 from 31st August 2020 until 21st May 2021. Twice weekly mass testing using LFTs have helped to control within-school transmission in secondary schools in England. A strategy of serial contact testing alongside mass testing substantially reduces absences compared to strategies involving isolating close contacts, with only a marginal increase in within-school transmission.InterpretationSecondary school control strategies involving mass testing have the potential to control within-school transmission while substantially reducing absences compared to an isolation of close contacts policy.

Published

2021

47. How modelling can help steer the course set by the World Health Organization 2021-2030 roadmap on neglected tropical diseases

Author

Graham F. Medley, Zulma M. Cucunubá, Kat S. Rock, Louise Dyson, Matthew A. Dixon, Timothy M Pollington, Henrik Salje, Katie Hampson, Joaquin M. Prada, Michael Marks, María-Gloria Basáñez, Luc E. Coffeng, Wilma A. Stolk, T. Déirdre Hollingsworth, Jessica Clark, and Jaspreet Toor

Subjects

Sustainable development, medicine.medical_specialty, Economic growth, Transmission (medicine), Health Policy, Public health, 030231 tropical medicine, Public Health, Environmental and Occupational Health, Medicine (miscellaneous), medicine.disease, Biochemistry, Genetics and Molecular Biology (miscellaneous), 03 medical and health sciences, 0302 clinical medicine, Geography, Visceral leishmaniasis, Immunology and Microbiology (miscellaneous), Trachoma, medicine, Neglected tropical diseases, 030212 general & internal medicine, Onchocerciasis, Lymphatic filariasis

Abstract

The World Health Organization recently launched its 2021-2030 roadmap, Ending the Neglect to Attain the Sustainable Development Goals, an updated call to arms to end the suffering caused by neglected tropical diseases. Modelling and quantitative analyses played a significant role in forming these latest goals. In this collection, we discuss the insights, the resulting recommendations and identified challenges of public health modelling for 13 of the target diseases: Chagas disease, dengue, gambiense human African trypanosomiasis (gHAT), lymphatic filariasis (LF), onchocerciasis, rabies, scabies, schistosomiasis, soil-transmitted helminthiases (STH), Taenia solium taeniasis/ cysticercosis, trachoma, visceral leishmaniasis (VL) and yaws. This piece reflects the three cross-cutting themes identified across the collection, regarding the contribution that modelling can make to timelines, programme design, drug development and clinical trials.

Published

2021

48. Possible future waves of SARS-CoV-2 infection generated by variants of concern with a range of characteristics

Author

Matthew James Keeling, Lorenzo Pellis, Sam Moore, Michael J. Tildesley, Louise Dyson, Edward M. Hill, Jacob Curran-Sebastian, Thomas House, and Katrina A. Lythgoe

Subjects

Adult, 2019-20 coronavirus outbreak, COVID-19 Vaccines, Coronavirus disease 2019 (COVID-19), Adolescent, Range (biology), Epidemiology, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Science, General Physics and Astronomy, Computational biology, Biology, Models, Biological, Virus, General Biochemistry, Genetics and Molecular Biology, Article, law.invention, Young Adult, Disease severity, Immunity, law, Pandemic, Humans, Computational models, Computer Simulation, Pandemics, Immune Evasion, QR355, Genetics, Stochastic Processes, Multidisciplinary, SARS-CoV-2, Vaccination, Immune escape, COVID-19, General Chemistry, Middle Aged, Transmissibility (vibration), United Kingdom, Transmission (mechanics), Homogeneous, Mutation, RA, Forecasting

Abstract

Viral reproduction of SARS-CoV-2 provides opportunities for the acquisition of advantageous mutations, altering viral transmissibility, disease severity, and/or allowing escape from natural or vaccine-derived immunity. We use three mathematical models: a parsimonious deterministic model with homogeneous mixing; an age-structured model; and a stochastic importation model to investigate the effect of potential variants of concern (VOCs). Calibrating to the situation in England in May 2021, we find epidemiological trajectories for putative VOCs are wide-ranging and dependent on their transmissibility, immune escape capability, and the introduction timing of a postulated VOC-targeted vaccine. We demonstrate that a VOC with a substantial transmission advantage over resident variants, or with immune escape properties, can generate a wave of infections and hospitalisations comparable to the winter 2020-2021 wave. Moreover, a variant that is less transmissible, but shows partial immune-escape could provoke a wave of infection that would not be revealed until control measures are further relaxed., Understanding the potential impacts of new variants of SARS-CoV-2 is important for pandemic planning. Here, the authors develop a model incorporating hypothetical new variants with varying transmissibility and immune evasion properties, and use it to project possible future epidemic waves in the UK.

Published

2021

49. Early epidemiological signatures of novel SARS-CoV-2 variants: establishment of B.1.617.2 in England

Author

Julia R. Gog, Matthew James Keeling, David J Pascall, Helena B. Stage, Francesca Scarabel, Michael J. Tildesley, Leon Danon, Jonathan M Read, Ben Youngman, Stefan Siegert, Ellen Brooks-Pollock, Laura Guzman-Rincon, Louise Dyson, Xiaoyu Xiong, Daniel Williamson, Paula Blomquist, Edward M. Hill, Robert Challen, Christopher E. Overton, and Lorenzo Pellis

Subjects

medicine.medical_specialty, 2019-20 coronavirus outbreak, Coronavirus disease 2019 (COVID-19), Routine testing, Transmission (medicine), Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Epidemiology, Pandemic, medicine, Biology, Virology

Abstract

The rapid emergence of SARS-CoV-2 mutants with new phenotypic properties is a critical challenge to the control of the ongoing pandemic. B.1.1.7 was monitored in the UK through routine testing and S-gene target failures (SGTF), comprising over 90% of cases by March 2021. Now, the reverse is occurring: SGTF cases are being replaced by an S-gene positive variant, which we associate with B.1.617.2. Evidence from the characteristics of S-gene positive cases demonstrates that, following importation, B.1.617.2 is transmitted locally, growing at a rate higher than B.1.1.7 and a doubling time between 5-14 days. S-gene positive cases should be prioritised for sequencing and aggressive control in any countries in which this variant is newly detected.One-Sentence SummaryThe B.1.617.2 variant of SARS-CoV-2 is replacing B.1.1.7 and emerging as the dominant variant in England, evidenced by sustained local transmission.

Published

2021

50. The impact of school reopening on the spread of COVID-19 in England

Author

Benjamin D. Atkins, Louise Dyson, Michael J. Tildesley, Emma Southall, Glen Guyver-Fletcher, Edward M. Hill, Bridget S. Penman, Matthew James Keeling, Hector McKimm, Alexander Holmes, and Erin E. Gorsich

Subjects

Adult, Male, endocrine system, medicine.medical_specialty, Adolescent, genetic structures, Coronavirus disease 2019 (COVID-19), Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Reproduction (economics), Secondary infection, Physical Distancing, education, Population, deterministic model, General Biochemistry, Genetics and Molecular Biology, Young Adult, RA0421, Political science, Critical threshold, Pandemic, medicine, Humans, mathematical modelling, Child, reopening schools, Pandemics, Research Articles, education.field_of_study, Schools, SARS-CoV-2, Mortality rate, Social distance, Public health, COVID-19, Articles, Models, Theoretical, England, Work (electrical), Child, Preschool, Communicable Disease Control, Model simulation, Female, Demographic economics, Psychology, General Agricultural and Biological Sciences

Abstract

Background In the UK, cases of COVID-19 have been declining since mid-April and there is good evidence to suggest that the effective reproduction number has dropped below 1, leading to a multiphase relaxation plan for the country to emerge from lockdown. As part of this staggered process, primary schools are scheduled to partially reopen on 1st June. Evidence from a range of sources suggests that children are, in general, only mildly affected by the disease and have low mortality rates, though there is less certainty regarding children’s role in transmission. Therefore, there is wide discussion on the impact of reopening schools. Methods We compare eight strategies for reopening primary and secondary schools in England from 1st June, focusing on the return of particular year groups and the associated epidemic consequences. This is assessed through model simulation, modifying a previously developed dynamic transmission model for SARS-CoV-2. We quantify how the process of reopening schools affected contact patterns and anticipated secondary infections, the relative change in R according to the extent of school reopening, and determine the public health impact via estimated change in clinical cases and its sensitivity to decreases in adherence post strict lockdown. Findings Whilst reopening schools, in any form, results in more mixing between children, an increase in R and hence transmission of the disease, the magnitude of that increase can be low dependent upon the age-groups that return to school and the behaviour of the remaining population. We predict that reopening schools in a way that allows half class sizes or that is focused on younger children is unlikely to push R above one, although there is noticeable variation between the regions of the country. Given that older children have a greater number of social contacts and hence a greater potential for transmission, our findings suggest reopening secondary schools results in larger increases in case burden than only reopening primary schools; reopening both generates the largest increase and could push R above one in some regions. The impact of less social-distancing in the rest of the population, generally has far larger effects than reopening schools and exacerbates the impacts of reopening. Discussion Our work indicates that any reopening of schools will result in increased mixing and infection amongst children and the wider population, although the opening of schools alone is unlikely to push the value of R above one. However, impacts of other recent relaxations of lockdown measures are yet to be quantified, suggesting some regions may be closer to the critical threshold that would lead to a growth in cases. Given the uncertainties, in part due to limited data on COVID-19 in children, school reopening should be carefully monitored. Ultimately, the decision about reopening classrooms is a difficult trade-off between increased epidemiological consequences and the emotional, educational and developmental needs of children.

Published

2021