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1. Within-host priority effects and epidemic timing determine outbreak severity in co-infected populations

   https://doi.org/10.1098/rspb.2020.0046  

   Clay, Patrick A.; Duffy, Meghan A.; Rudolf, Volker H. (March 2020, Proceedings of the Royal Society B: Biological Sciences)

   Co-infections of hosts by multiple pathogen species are ubiquitous, but predicting their impact on disease remains challenging. Interactions between co-infecting pathogens within hosts can alter pathogen transmission, with the impact on transmission typically dependent on the relative arrival order of pathogens within hosts (within-host priority effects). However, it is unclear how these within-host priority effects influence multi-pathogen epidemics, particularly when the arrival order of pathogens at the host-population scale varies. Here, we combined models and experiments with zooplankton and their naturally co-occurring fungal and bacterial pathogens to examine how within-host priority effects influence multi-pathogen epidemics. Epidemiological models parametrized with within-host priority effects measured at the single-host scale predicted that advancing the start date of bacterial epidemics relative to fungal epidemics would decrease the mean bacterial prevalence in a multi-pathogen setting, while models without within-host priority effects predicted the opposite effect. We tested these predictions with experimental multi-pathogen epidemics. Empirical dynamics matched predictions from the model including within-host priority effects, providing evidence that within-host priority effects influenced epidemic dynamics. Overall, within-host priority effects may be a key element of predicting multi-pathogen epidemic dynamics in the future, particularly as shifting disease phenology alters the order of infection within hosts. 

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2. Season of death, pathogen persistence and wildlife behaviour alter number of anthrax secondary infections from environmental reservoirs

   https://doi.org/10.1098/rspb.2023.2568  

   Dolfi, Amélie C; Kausrud, Kyrre; Rysava, Kristyna; Champagne, Celeste; Huang, Yen-Hua; Barandongo, Zoe R; Turner, Wendy C (February 2024, Proceedings of the Royal Society B: Biological Sciences)

   An important part of infectious disease management is predicting factors that influence disease outbreaks, such asR, the number of secondary infections arising from an infected individual. EstimatingRis particularly challenging for environmentally transmitted pathogens given time lags between cases and subsequent infections. Here, we calculatedRforBacillus anthracisinfections arising from anthrax carcass sites in Etosha National Park, Namibia. Combining host behavioural data, pathogen concentrations and simulation models, we show thatRis spatially and temporally variable, driven by spore concentrations at death, host visitation rates and early preference for foraging at infectious sites. While spores were detected up to a decade after death, most secondary infections occurred within 2 years. Transmission simulations under scenarios combining site infectiousness and host exposure risk under different environmental conditions led to dramatically different outbreak dynamics, from pathogen extinction (R< 1) to explosive outbreaks (R> 10). These transmission heterogeneities may explain variation in anthrax outbreak dynamics observed globally, and more generally, the critical importance of environmental variation underlying host–pathogen interactions. Notably, our approach allowed us to estimate the lethal dose of a highly virulent pathogen non-invasively from observational studies and epidemiological data, useful when experiments on wildlife are undesirable or impractical. 

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3. Comparative analysis of practical identifiability methods for an SEIR model

   https://doi.org/10.3934/math.20241204  

   Saucedo, Omar; Laubmeier, Amanda; Tang, Tingting; Levy, Benjamin; Asik, Lale; Pollington, Tim; Feldman, Olivia Prosper (August 2024, AIMS Mathematics)

   Identifiability of a mathematical model plays a crucial role in the parameterization of the model. In this study, we established the structural identifiability of a susceptible-exposed-infected-recovered (SEIR) model given different combinations of input data and investigated practical identifiability with respect to different observable data, data frequency, and noise distributions. The practical identifiability was explored by both Monte Carlo simulations and a correlation matrix approach. Our results showed that practical identifiability benefits from higher data frequency and data from the peak of an outbreak. The incidence data gave the best practical identifiability results compared to prevalence and cumulative data. In addition, we compared and distinguished the practical identifiability by Monte Carlo simulations and a correlation matrix approach, providing insights into when to use which method for other applications. 

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4. Emergence and interstate spread of highly pathogenic avian influenza A(H5N1) in dairy cattle in the United States

   https://doi.org/10.1126/science.adq0900  

   Nguyen, Thao-Quyen; Hutter, Carl R; Markin, Alexey; Thomas, Megan; Lantz, Kristina; Killian, Mary Lea; Janzen, Garrett M; Vijendran, Sriram; Wagle, Sanket; Inderski, Blake; et al (April 2025, Science)

   Highly pathogenic avian influenza (HPAI) viruses cross species barriers and have the potential to cause pandemics. In North America, HPAI A(H5N1) viruses related to the goose/Guangdong 2.3.4.4b hemagglutinin phylogenetic clade have infected wild birds, poultry, and mammals. Our genomic analysis and epidemiological investigation showed that a reassortment event in wild bird populations preceded a single wild bird–to-cattle transmission episode. The movement of asymptomatic or presymptomatic cattle has likely played a role in the spread of HPAI within the United States dairy herd. Some molecular markers that may lead to changes in transmission efficiency and phenotype were detected at low frequencies. Continued transmission of H5N1 HPAI within dairy cattle increases the risk for infection and subsequent spread of the virus to human populations. 

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5. Sampling and summarizing transmission trees with multi-strain infections

   https://doi.org/10.1093/bioinformatics/btaa438  

   Sashittal, Palash; El-Kebir, Mohammed (July 2020, Bioinformatics)

   null (Ed.)

   Abstract Motivation The combination of genomic and epidemiological data holds the potential to enable accurate pathogen transmission history inference. However, the inference of outbreak transmission histories remains challenging due to various factors such as within-host pathogen diversity and multi-strain infections. Current computational methods ignore within-host diversity and/or multi-strain infections, often failing to accurately infer the transmission history. Thus, there is a need for efficient computational methods for transmission tree inference that accommodate the complexities of real data. Results We formulate the direct transmission inference (DTI) problem for inferring transmission trees that support multi-strain infections given a timed phylogeny and additional epidemiological data. We establish hardness for the decision and counting version of the DTI problem. We introduce Transmission Tree Uniform Sampler (TiTUS), a method that uses SATISFIABILITY to almost uniformly sample from the space of transmission trees. We introduce criteria that prioritize parsimonious transmission trees that we subsequently summarize using a novel consensus tree approach. We demonstrate TiTUS’s ability to accurately reconstruct transmission trees on simulated data as well as a documented HIV transmission chain. Availability and implementation https://github.com/elkebir-group/TiTUS. Supplementary information Supplementary data are available at Bioinformatics online. 

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