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Benjamin Bolker Person1 #679758 I’m a professor in the departments of Mathematics & Statistics and of Biology at McMaster University, and currently Director of the School of Computational Science and Engineering and Acting Associate Chair (Graduate) for Mathematics. | - My interests range widely in spatial, theoretical, mathematical, computational and statistical ecology, evolution and epidemiology; plant community, ecosystem, and epidemic dynamics; and whatever else takes my fancy.
- I run the mac-theobio research group jointly with Jonathan Dushoff and David Earn.
Tags: Ben Bolker |
+Citations (7) - CitationsAjouter une citationList by: CiterankMapLink[4] Infectious Disease: A Very Short Introduction
En citant: Marta Wayne, Benjamin Bolker Publication date: 25 June 2015 Publication info: Oxford University Press, Online ISBN: 9780191785276,
Print ISBN: 9780199688937 Cité par: David Price 3:25 PM 1 October 2022 GMT URL: DOI: https://doi.org/10.1093/actrade/9780199688937.001.0001
| Extrait - Infectious disease is a moving target: new diseases emerge every year, old diseases evolve into new forms, and ecological and socioeconomic upheavals change the transmission pathways by which diseases spread. By taking an approach focused on the general evolutionary and ecological dynamics of disease, Infectious Disease: A Very Short Introduction considers where particular diseases come from, how they are transmitted from one person to another, why some individuals are more susceptible than others, and what strategies can be used to combat these diseases. It explains the general principles of infection, the management of outbreaks, and the evolutionary and ecological approaches that are now central to much research about infectious disease. |
Link[5] Evaluating undercounts in epidemics: response to Maruotti et al. 2022
En citant: Michael Li, Jonathan Dushoff, David J. D. Earn, Benjamin M. Bolker Publication date: 22 September 2022 Publication info: arXiv:2209.11334 [q-bio.PE] Cité par: David Price 12:15 PM 25 November 2023 GMT Citerank: (6) 679776David EarnProfessor of Mathematics and Faculty of Science Research Chair in Mathematical Epidemiology at McMaster University.10019D3ABAB, 679814Jonathan DushoffProfessor in the Department Of Biology at McMaster University.10019D3ABAB, 685445Michael WZ LiMichael Li is Senior Scientist in the Public Health Risk Science Division (PHRS) of the Public Health Agency of Canada (PHAC) and a Research Associate at the South African Centre for Epidemiological Modelling and Analysis (SACEMA).10019D3ABAB, 701020CANMOD – PublicationsPublications by CANMOD Members144B5ACA0, 701037MfPH – Publications144B5ACA0, 715667mpox859FDEF6 URL: DOI: https://doi.org/10.48550/arXiv.2209.11334
| Extrait - [arXiv, 22 September 2022]
Maruotti et al. 2022 used a mark-recapture approach to estimate bounds on the true number of monkeypox infections in various countries. These approaches are fundamentally flawed; it is impossible to estimate undercounting based solely on a single stream of reported cases. Simulations based on a Richards curve for cumulative incidence show that, for reasonable epidemic parameters, the proposed methods estimate bounds on the ascertainment ratio of ≈0.2−0.5 roughly independently of the true ascertainment ratio. These methods should not be used. |
Link[6] Predicting the Temperature-Driven Development of Stage-Structured Insect Populations with a Bayesian Hierarchical Model
En citant: Kala Studens, Benjamin M. Bolker, Jean-Noël Candau Publication date: 16 November 2023 Publication info: JABES (2023) Cité par: David Price 5:26 PM 8 December 2023 GMT Citerank: (2) 701020CANMOD – PublicationsPublications by CANMOD Members144B5ACA0, 708748Arthropods859FDEF6 URL: DOI: https://doi.org/10.1007/s13253-023-00581-y
| Extrait - [Journal of Agricultural, Biological and Environmental Statistics, 16 November 2023]
The management of forest pests relies on an accurate understanding of the species’ phenology. Thermal performance curves (TPCs) have traditionally been used to model insect phenology. Many such models have been proposed and fitted to data from both wild and laboratory-reared populations. Using Hamiltonian Monte Carlo for estimation, we implement and fit an individual-level, Bayesian hierarchical model of insect development to the observed larval stage durations of a population reared in a laboratory at constant temperatures. This hierarchical model handles interval censoring and temperature transfers between two constant temperatures during rearing. It also incorporates individual variation, quadratic variation in development rates across insects’ larval stages, and “flexibility” parameters that allow for deviations from a parametric TPC. Using a Bayesian method ensures a proper propagation of parameter uncertainty into predictions and provides insights into the model at hand. The model is applied to a population of eastern spruce budworm (Choristoneura fumiferana) reared at 7 constant temperatures. Resulting posterior distributions can be incorporated into a workflow that provides prediction intervals for the timing of life stages under different temperature regimes. We provide a basic example for the spruce budworm using a year of hourly temperature data from Timmins, Ontario, Canada. Supplementary materials accompanying this paper appear on-line. |
Link[7] The probability of epidemic burnout in the stochastic SIR model with vital dynamics
En citant: Todd L. Parsons, Benjamin M. Bolker, Jonathan Dushoff, David J. D. Earn Publication date: 26 January 2024 Publication info: PNAS, 121 (5) e2313708120 Cité par: David Price 1:10 AM 28 February 2024 GMT Citerank: (3) 679776David EarnProfessor of Mathematics and Faculty of Science Research Chair in Mathematical Epidemiology at McMaster University.10019D3ABAB, 679814Jonathan DushoffProfessor in the Department Of Biology at McMaster University.10019D3ABAB, 701020CANMOD – PublicationsPublications by CANMOD Members144B5ACA0 URL: DOI: https://doi.org/10.1073/pnas.2313708120
| Extrait - [PNAS, 26 January 2024]
If a new pathogen causes a large epidemic, then it might “burn out” before causing a second epidemic. The burnout probability can be estimated from large numbers of computationally intensive simulations, but an easily computable formula for the burnout probability has never been found. Using a conceptually simple approach, we derive such a formula for the standard SIR epidemic model with vital dynamics (host births and deaths). With this formula, we show that the burnout probability is always smaller for diseases with longer infectious periods, but is bimodal with respect to transmissibility (the basic reproduction number). Our analysis shows that the persistence of typical human infectious diseases cannot be explained by births of new susceptibles, clarifying an important epidemiological puzzle… |
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