Contributors
Hayriye Gulbudak, University of Louisiana at Lafayette. Title:Modeling across-scale feedbacks of infectious diseases:
Abba B Gumel, Arizona State University. Title: Mathematics and the renewed quest for malaria eradication.
Abba B Gumel, Arizona State University. Title: Mathematics and the renewed quest for malaria eradication.
Institution/ Affiliation
Hayriye Gulbudak, University of Louisiana at Lafayette.
Abba B Gumel, Arizona State University.
Abba B Gumel, Arizona State University.
Presentation Details (date, conference, etc.)
February 24, 2022, IMAG/MSM WG on Multiscale Modeling and Viral Pandemics
- Hayriye Gulbudak, University of Louisiana at Lafayette, Modeling across-scale feedbacks of infectious diseases: A current challenge for disease modeling and public health is to understand pathogen dynamics across infection scales from within-host to between-host. Viral and immune response kinetics upon infection impact transmission to other hosts and feedback into population-wide immunity, all of which influence the severity, trajectory, and evolution of a spreading pathogen. In this talk, I will introduce structured partial differential equation models linking immunology and epidemiology in order to investigate coevolution of virus and host, multi-scale data fitting, and impacts of dynamic host immunity from an individual to the whole population. We apply the models to vector-borne diseases, such as Rift Valley fever (RVF) and dengue (DENV), with immunological and epidemiological data. Using invasion dynamics analysis and multi-scale numerical methods, we characterize different scenarios of virus-host evolution and coexistence of viral strains under waning host cross-immunity. In the case of DENV, we recapitulate how intermediate levels of pre-existent antibodies enhance infection within a host, and how to scale up to distributions of antibody levels among epidemiological classes in the host population to determine risk of severe DENV prevalence. These results have implications for optimal vaccination policy, and the modeling framework developed here is currently being applied to examine the emergence of COVID-19 variants partially resistant to antibodies induced by host infection or vaccination. YouTube and Slides.
- "Infection severity across scales in multi-strain immuno-epidemiological Dengue model structured by host antibody level" https://link.springer.com/article/10.1007/s00285-020-01480-3
- "Vector-Borne Pathogen and Host Evolution in a Structured Immuno-Epidemiological System" https://link.springer.com/article/10.1007/s11538-016-0239-0
- "An Immuno-Epidemiological Vector–Host Model with Within-Vector Viral Kinetics" https://www.worldscientific.com/doi/abs/10.1142/S0218339020400021
- Abba B Gumel, Arizona State University, Mathematics and the renewed quest for malaria eradication: The widespread use of insecticide-based interventions against malaria mosquitoes over the last two decades has led to a dramatic reduction in global malaria burden, prompting a renewed quest to eradicate the disease by 2030 or 2040. Unfortunately, such heavy use of insecticides has also resulted in widespread resistance (in the malaria vector population) to all the currently available insecticides used in vector control. In this lecture, I will briefly present a genetics-epidemiology modeling framework for assessing the impacts of insecticide resistance and climate change on malaria transmission dynamics, with emphasis on determining whether the malaria eradication objective can be achieved using existing vector control resources. YouTube and Slides.
- “Weather-driven malaria transmission model with gonotrophic and sporogonic cycles” https://pubmed.ncbi.nlm.nih.gov/30691351/
- “Insecticide resistance and malaria control: A genetics-epidemiology modeling approach” https://pubmed.ncbi.nlm.nih.gov/32437715/