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SMMEID – Publications Document1 #715387
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+Citaten (6) - CitatenVoeg citaat toeList by: CiterankMapLink[1] A Framework for Incorporating Behavioural Change into Individual-Level Spatial Epidemic Models
Citerend uit: Madeline A. Ward, Rob Deardon, Lorna E. Deeth Publication date: 1 August 2023 Publication info: arXiv:2308.00815v1 [stat.ME] Geciteerd door: David Price 10:28 PM 16 November 2023 GMT Citerank: (2) 679869Rob DeardonAssociate Professor in the Department of Production Animal Health in the Faculty of Veterinary Medicine and the Department of Mathematics and Statistics in the Faculty of Science at the University of Calgary.10019D3ABAB, 715386Madeline WardMadeline A. Ward is a PHD student in Biostatistics in the Department of Mathematics and Statistics at the University of Calgary.10019D3ABAB URL: DOI: https://doi.org/10.48550/arXiv.2308.00815
| Fragment- [arXiv, 1 August 2023]
During epidemics, people will often modify their behaviour patterns over time in response to changes in their perceived risk of spreading or contracting the disease. This can substantially impact the trajectory of the epidemic. However, most infectious disease models assume stable population behaviour due to the challenges of modelling these changes. We present a flexible new class of models, called behavioural change individual-level models (BC-ILMs), that incorporate both individual-level covariate information and a data-driven behavioural change effect. Focusing on spatial BC-ILMs, we consider four "alarm" functions to model the effect of behavioural change as a function of infection prevalence over time. We show how these models can be estimated in a simulation setting. We investigate the impact of misspecifying the alarm function when fitting a BC-ILM, and find that if behavioural change is present in a population, using an incorrect alarm function will still result in an improvement in posterior predictive performance over a model that assumes stable population behaviour. We also find that using spike and slab priors on alarm function parameters is a simple and effective method to determine whether a behavioural change effect is present in a population. Finally, we show results from fitting spatial BC-ILMs to data from the 2001 U.K. foot and mouth disease epidemic. |
Link[2] Bayesian modeling of dynamic behavioral change during an epidemic
Citerend uit: Caitlin Ward, Rob Deardon, Alexandra M. Schmidt Publication date: 11 August 2023 Publication info: Infectious Disease Modelling, Volume 8, Issue 4,
2023, Pages 947-963, ISSN 2468-0427, Geciteerd door: David Price 10:36 PM 16 November 2023 GMT Citerank: (1) 679869Rob DeardonAssociate Professor in the Department of Production Animal Health in the Faculty of Veterinary Medicine and the Department of Mathematics and Statistics in the Faculty of Science at the University of Calgary.10019D3ABAB URL: DOI: https://doi.org/10.1016/j.idm.2023.08.002
| Fragment- [Infectious Disease Modelling, 11 August 2023]
For many infectious disease outbreaks, the at-risk population changes their behavior in response to the outbreak severity, causing the transmission dynamics to change in real-time. Behavioral change is often ignored in epidemic modeling efforts, making these models less useful than they could be. We address this by introducing a novel class of data-driven epidemic models which characterize and accurately estimate behavioral change. Our proposed model allows time-varying transmission to be captured by the level of “alarm” in the population, with alarm specified as a function of the past epidemic trajectory. We investigate the estimability of the population alarm across a wide range of scenarios, applying both parametric functions and non-parametric functions using splines and Gaussian processes. The model is set in the data-augmented Bayesian framework to allow estimation on partially observed epidemic data. The benefit and utility of the proposed approach is illustrated through applications to data from real epidemics. |
Link[3] Omicron BA.1/1.1 SARS-CoV-2 Infection among Vaccinated Canadian Adults
Citerend uit: Patrick E. Brown, Sze Hang Fu, Aiyush Bansal, et al., Ab-C Study Collaborators Publication date: 16 June 2022 Publication info: N Engl J Med 2022; 386:2337-2339, June 16, 2022
Geciteerd door: David Price 10:37 PM 17 November 2023 GMT Citerank: (1) 679858Patrick BrownAssociate Professor in the Centre for Global Health Research at St. Michael’s Hospital, and in the Department of Statistical Sciences at the University of Toronto.10019D3ABAB URL: DOI: https://doi.org/10.1056/NEJMc2202879
| Fragment- [New England Journal of Medicine, 16 June 2022]
The incidence of the omicron BA.1/1.1 variant of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), which rapidly spread worldwide even among vaccinated persons, is incompletely defined. We quantified the incidence of SARS-CoV-2 infection during the initial omicron BA.1/1.1 variant wave among Canadian adults and the contribution of previous infection and concurrent vaccination to age-specific active immunity… |
Link[4] COVID-19 vaccines: a geographic, social and policy view of vaccination efforts in Ontario, Canada
Citerend uit: Isaac I Bogoch, Sheliza Halani Publication date: 23 November 2022 Publication info: Cambridge Journal of Regions, Economy and Society, Volume 15, Issue 3, November 2022, Pages 757–770 Geciteerd door: David Price 10:55 PM 17 November 2023 GMT Citerank: (1) 679802Isaac BogochClinician Investigator, Toronto General Hospital Research Institute (TGHRI)10019D3ABAB URL: DOI: https://doi.org/10.1093/cjres/rsac043
| Fragment- [Cambridge Journal of Regions, Economy and Society, 23 November 2022]
In recent months, more studies are emerging regarding how various nations and regions fared during the initial two years of the COVID-19 pandemic. Canada is cited as an example of a country that had performed reasonably well versus other countries with comparable infrastructures and health care systems (Razek et al., 2022). The reason is largely attributed to a combination of several public health measures coupled with widespread vaccination uptake, as a result of a country-wide vaccination campaign. This paper is based on a keynote talk given at the Autumn 2021 CJRES Annual Conference, by Dr. Isaac I. Bogoch. Dr Bogoch is an Associate Professor in the Department of Medicine at the University of Toronto, and an Infectious Diseases Consultant in the Division of Infectious Diseases at the Toronto General Hospital. Dr. Bogoch was a member of Ontario’s Vaccine Distribution Taskforce, which helped guide vaccine policy during the initial rollout of COVID-19 vaccines between December 2020 through August 2021. Dr. Bogoch explains the unique vaccine policy in the Province of Ontario and in particular the social innovation around prioritising the most vulnerable and disadvantaged neighbourhoods first, thus leading to an important intra-regional social policy view of vaccine efforts on the path beyond the ‘emergency phase’ of the COVID-19 pandemic. What is clearly obvious from his presentation is the heightened role of urban geography tools and techniques and intra-regional policy in vaccine equity efforts. Policy lessons learned in Ontario may help us sort out future urban, social, economic, epidemiologic and public health challenges and their sometimes-complex intersections in regions, economy and society. |
Link[5] Predicting COVID-19 mortality risk in Toronto, Canada: a comparison of tree-based and regression-based machine learning methods
Citerend uit: Cindy Feng, George Kephart, Elizabeth Juarez-Colunga Publication date: 27 November 2021 Publication info: BMC Med Res Methodol. 2021 Nov 27;21(1):267. Geciteerd door: David Price 11:25 PM 17 November 2023 GMT Citerank: (1) 679771Cindy FengAssociate Professor in the Department of Community Health and Epidemiology in the Faculty of Medicine at Dalhousie University.10019D3ABAB URL: DOI: https://doi.org/10.1186/s12874-021-01441-4
| Fragment- [BMC Medical Research Methodology, 27 November 2021]
Background: Coronavirus disease (COVID-19) presents an unprecedented threat to global health worldwide. Accurately predicting the mortality risk among the infected individuals is crucial for prioritizing medical care and mitigating the healthcare system's burden. The present study aimed to assess the predictive accuracy of machine learning methods to predict the COVID-19 mortality risk.
Methods: We compared the performance of classification tree, random forest (RF), extreme gradient boosting (XGBoost), logistic regression, generalized additive model (GAM) and linear discriminant analysis (LDA) to predict the mortality risk among 49,216 COVID-19 positive cases in Toronto, Canada, reported from March 1 to December 10, 2020. We used repeated split-sample validation and k-steps-ahead forecasting validation. Predictive models were estimated using training samples, and predictive accuracy of the methods for the testing samples was assessed using the area under the receiver operating characteristic curve, Brier's score, calibration intercept and calibration slope.
Results: We found XGBoost is highly discriminative, with an AUC of 0.9669 and has superior performance over conventional tree-based methods, i.e., classification tree or RF methods for predicting COVID-19 mortality risk. Regression-based methods (logistic, GAM and LASSO) had comparable performance to the XGBoost with slightly lower AUCs and higher Brier's scores.
Conclusions: XGBoost offers superior performance over conventional tree-based methods and minor improvement over regression-based methods for predicting COVID-19 mortality risk in the study population. |
Link[6] Charting a future for emerging infectious disease modelling in Canada
Citerend uit: Mark A. Lewis, Patrick Brown, Caroline Colijn, Laura Cowen, Christopher Cotton, Troy Day, Rob Deardon, David Earn, Deirdre Haskell, Jane Heffernan, Patrick Leighton, Kumar Murty, Sarah Otto, Ellen Rafferty, Carolyn Hughes Tuohy, Jianhong Wu, Huaiping Zhu Publication date: 26 April 2023 Geciteerd door: David Price 2:30 PM 19 November 2023 GMT
Citerank: (22) 679703EIDM?The Emerging Infectious Diseases Modelling Initiative (EIDM) – by the Public Health Agency of Canada and NSERC – aims to establish multi-disciplinary network(s) of specialists across the country in modelling infectious diseases to be applied to public needs associated with emerging infectious diseases and pandemics such as COVID-19. [1]7F1CEB7, 679761Caroline ColijnDr. Caroline Colijn works at the interface of mathematics, evolution, infection and public health, and leads the MAGPIE research group. She joined SFU's Mathematics Department in 2018 as a Canada 150 Research Chair in Mathematics for Infection, Evolution and Public Health. She has broad interests in applications of mathematics to questions in evolution and public health, and was a founding member of Imperial College London's Centre for the Mathematics of Precision Healthcare.10019D3ABAB, 679769Christopher CottonChristopher Cotton is a Professor of Economics at Queen’s University where he holds the Jarislowsky-Deutsch Chair in Economic & Financial Policy.10019D3ABAB, 679776David EarnProfessor of Mathematics and Faculty of Science Research Chair in Mathematical Epidemiology at McMaster University.10019D3ABAB, 679797Huaiping ZhuProfessor of mathematics at the Department of Mathematics and Statistics at York University, a York Research Chair (YRC Tier I) in Applied Mathematics, the Director of the Laboratory of Mathematical Parallel Systems at the York University (LAMPS), the Director of the Canadian Centre for Diseases Modelling (CCDM) and the Director of the One Health Modelling Network for Emerging Infections (OMNI-RÉUNIS). 10019D3ABAB, 679806Jane HeffernanJane Heffernan is a professor of infectious disease modelling in the Mathematics & Statistics Department at York University. She is a co-director of the Canadian Centre for Disease Modelling, and she leads national and international networks in mathematical immunology and the modelling of waning and boosting immunity.10019D3ABAB, 679812Jianhong WuProfessor Jianhong Wu is a University Distinguished Research Professor and Senior Canada Research Chair in industrial and applied mathematics at York University. He is also the NSERC Industrial Research Chair in vaccine mathematics, modelling, and manufacturing. 10019D3ABAB, 679826Laura CowenAssociate Professor in the Department of Mathematics and Statistics at the University of Victoria.10019D3ABAB, 679842Mark LewisProfessor Mark Lewis, Kennedy Chair in Mathematical Biology at the University of Victoria and Emeritus Professor at the University of Alberta.10019D3ABAB, 679858Patrick BrownAssociate Professor in the Centre for Global Health Research at St. Michael’s Hospital, and in the Department of Statistical Sciences at the University of Toronto.10019D3ABAB, 679859Patrick LeightonPatrick Leighton is a Professor of Epidemiology and Public Health at the Faculty of Veterinary Medicine, University of Montreal, and an active member of the Epidemiology of Zoonoses and Public Health Research Group (GREZOSP) and the Centre for Public Health Research (CReSP). 10019D3ABAB, 679869Rob DeardonAssociate Professor in the Department of Production Animal Health in the Faculty of Veterinary Medicine and the Department of Mathematics and Statistics in the Faculty of Science at the University of Calgary.10019D3ABAB, 679875Sarah OttoProfessor in Zoology. Theoretical biologist, Canada Research Chair in Theoretical and Experimental Evolution, and Killam Professor at the University of British Columbia.10019D3ABAB, 679890Troy DayTroy Day is a Professor and the Associate Head of the Department of Mathematics and Statistics at Queen’s University. He is an applied mathematician whose research focuses on dynamical systems, optimization, and game theory, applied to models of infectious disease dynamics and evolutionary biology.10019D3ABAB, 679893Kumar MurtyProfessor Kumar Murty is in the Department of Mathematics at the University of Toronto. His research fields are Analytic Number Theory, Algebraic Number Theory, Arithmetic Algebraic Geometry and Information Security. He is the founder of the GANITA lab, co-founder of Prata Technologies and PerfectCloud. His interest in mathematics ranges from the pure study of the subject to its applications in data and information security.10019D3ABAB, 686724Ellen RaffertyDr. Ellen Rafferty has a Master of Public Health and a PhD in epidemiology and health economics from the University of Saskatchewan. Dr. Rafferty’s research focuses on the epidemiologic and economic impact of public health policies, such as estimating the cost-effectiveness of immunization programs. She is interested in the incorporation of economics into immunization decision-making, and to that aim has worked with a variety of provincial and national organizations.10019D3ABAB, 701020CANMOD – PublicationsPublications by CANMOD Members144B5ACA0, 701037MfPH – Publications144B5ACA0, 701071OSN – Publications144B5ACA0, 701222OMNI – Publications144B5ACA0, 704045Covid-19859FDEF6, 714608Charting a FutureCharting a Future for Emerging Infectious Disease Modelling in Canada – April 2023 [1] 2794CAE1 URL:
| Fragment- We propose an independent institute of emerging infectious disease modellers and policy experts, with an academic core, capable of renewing itself as needed. This institute will combine science and knowledge translation to inform decision-makers at all levels of government and ensure the highest level of preparedness (and readiness) for the next public health emergency. The Public Health Modelling Institute will provide cost-effective, science-based modelling for public policymakers in an easily visualizable, integrated framework, which can respond in an agile manner to changing needs, questions, and data. To be effective, the Institute must link to modelling groups within government, who are best able to pose questions and convey results for use by public policymakers. |
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