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Alexander Rutherford Person1 #679748 Dr. Rutherford is the Director for the CSMG. Prior to joining the CSMG, he was the Scientific Executive Officer at the Pacific Institute for the Mathematical Sciences (PIMS). | - Dr. Rutherford holds a Ph.D. in Mathematical Physics from the University of British Columbia and held postdoctoral fellowships at the Swiss Federal Institute of Technology (ETH) in Zurich, Switzerland, and the International School for Advanced Studies (SISSA) in Trieste, Italy. His research spans a wide range of fields within the mathematical sciences. In mathematical physics, his main focus has been on quantum-mechanical many-body problems. In health research, he worked on the design and evaluation of protocols for electronic health records and applications of queuing theory to surgical waitlists and the acute care system. He has also worked on application of dynamical systems methods to health care modelling, criminal justice system modelling, and epidemiology.
Tags: Sandy Rutherford |
+Citations (3) - CitationsAdd new citationList by: CiterankMapLink[2] A queuing model for ventilator capacity management during the COVID-19 pandemic
Author: Samantha L. Zimmerman, Alexander R. Rutherford, Alexa van der Waall, Monica Norena, Peter Dodek Publication date: 23 May 2023 Publication info: Health Care Management Science, 22 May 2023, Volume 26, pages 200–216 (2023) Cited by: David Price 4:48 PM 11 December 2023 GMT Citerank: (3) 701020CANMOD – PublicationsPublications by CANMOD Members144B5ACA0, 704045Covid-19859FDEF6, 714608Charting a FutureCharting a Future for Emerging Infectious Disease Modelling in Canada – April 2023 [1] 2794CAE1 URL: DOI: https://doi.org/10.1007/s10729-023-09632-9
| Excerpt / Summary [Health Care Management Science, 22 May 2023]
We applied a queuing model to inform ventilator capacity planning during the first wave of the COVID-19 epidemic in the province of British Columbia (BC), Canada. The core of our framework is a multi-class Erlang loss model that represents ventilator use by both COVID-19 and non-COVID-19 patients. Input for the model includes COVID-19 case projections, and our analysis incorporates projections with different levels of transmission due to public health measures and social distancing. We incorporated data from the BC Intensive Care Unit Database to calibrate and validate the model. Using discrete event simulation, we projected ventilator access, including when capacity would be reached and how many patients would be unable to access a ventilator. Simulation results were compared with three numerical approximation methods, namely pointwise stationary approximation, modified offered load, and fixed point approximation. Using this comparison, we developed a hybrid optimization approach to efficiently identify required ventilator capacity to meet access targets. Model projections demonstrate that public health measures and social distancing potentially averted up to 50 deaths per day in BC, by ensuring that ventilator capacity was not reached during the first wave of COVID-19. Without these measures, an additional 173 ventilators would have been required to ensure that at least 95% of patients can access a ventilator immediately. Our model enables policy makers to estimate critical care utilization based on epidemic projections with different transmission levels, thereby providing a tool to quantify the interplay between public health measures, necessary critical care resources, and patient access indicators. |
Link[3] Pneumococcal population dynamics: Investigating vaccine-induced changes through multiscale modelling
Author: Nicola Mulberry, Alexander R. Rutherford, Caroline Colijn Publication date: 28 December 2023 Publication info: PLoS Comput Biol 19(12): e1011755 Cited by: David Price 9:24 PM 10 January 2024 GMT Citerank: (3) 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, 701020CANMOD – PublicationsPublications by CANMOD Members144B5ACA0, 716661Streptococcus pneumoniae859FDEF6 URL: DOI: https://doi.org/10.1371/journal.pcbi.1011755
| Excerpt / Summary [PLoS Computational Biology, 28 December 2023]
The mechanisms behind vaccine-induced strain replacement in the pneumococcus remain poorly understood. There is emerging evidence that distinct pneumococcal lineages can co-colonise for significant time periods, and that novel recombinants can readily emerge during natural colonisation. Despite this, patterns of post-vaccine replacement are indicative of competition between specific lineages. Here, we develop a multiscale transmission model to investigate explicitly how within host dynamics shape observed ecological patterns, both pre- and post-vaccination. Our model framework explores competition between and within strains defined by distinct antigenic, metabolic and resistance profiles. We allow for strains to freely co-colonise and recombine within hosts, and consider how each of these types may contribute to a strain’s overall fitness. Our results suggest that antigenic and resistance profiles are key drivers of post-vaccine success. |
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