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Heterogeneity, Mixing, and the Spatial Scales of Mosquito-Borne Pathogen Transmission

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  • T Alex Perkins
  • Thomas W Scott
  • Arnaud Le Menach
  • David L Smith

Abstract

The Ross-Macdonald model has dominated theory for mosquito-borne pathogen transmission dynamics and control for over a century. The model, like many other basic population models, makes the mathematically convenient assumption that populations are well mixed; i.e., that each mosquito is equally likely to bite any vertebrate host. This assumption raises questions about the validity and utility of current theory because it is in conflict with preponderant empirical evidence that transmission is heterogeneous. Here, we propose a new dynamic framework that is realistic enough to describe biological causes of heterogeneous transmission of mosquito-borne pathogens of humans, yet tractable enough to provide a basis for developing and improving general theory. The framework is based on the ecological context of mosquito blood meals and the fine-scale movements of individual mosquitoes and human hosts that give rise to heterogeneous transmission. Using this framework, we describe pathogen dispersion in terms of individual-level analogues of two classical quantities: vectorial capacity and the basic reproductive number, . Importantly, this framework explicitly accounts for three key components of overall heterogeneity in transmission: heterogeneous exposure, poor mixing, and finite host numbers. Using these tools, we propose two ways of characterizing the spatial scales of transmission—pathogen dispersion kernels and the evenness of mixing across scales of aggregation—and demonstrate the consequences of a model's choice of spatial scale for epidemic dynamics and for estimation of , both by a priori model formulas and by inference of the force of infection from time-series data.Author Summary: Pathogens transmitted by mosquitoes, such as malaria and dengue, are notorious for the biological complexity associated with how they are transmitted within local communities. Yet mathematical models for these pathogens, which are critical tools for making recommendations for control policy, are based around concepts originally designed to describe how molecules interact in chemical systems. To provide those interested in mosquito-borne diseases a more appropriate tool for modeling their transmission, we introduce a mathematical framework that is based on the spatial locations where mosquitoes lay eggs and feed on blood and how mosquitoes and hosts move about those locations. Analysis of this framework shows that the transmission contributions of different hosts and locations can be calculated, and that overall potential for transmission in a community depends on three concepts: heterogeneous exposure (some people bitten by mosquitoes more than others), poor mixing (non-random contacts between hosts and mosquitoes), and finite population sizes (each host can contribute at most one new infection towards the population total). Together, these factors determine critical levels of vaccination coverage to eliminate a pathogen and the spatial areas over which transmission should be modeled and studied in the field.

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  • T Alex Perkins & Thomas W Scott & Arnaud Le Menach & David L Smith, 2013. "Heterogeneity, Mixing, and the Spatial Scales of Mosquito-Borne Pathogen Transmission," PLOS Computational Biology, Public Library of Science, vol. 9(12), pages 1-16, December.
    • Handle: RePEc:plo:pcbi00:1003327
    DOI: 10.1371/journal.pcbi.1003327
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    1. Krisztian Magori & Mathieu Legros & Molly E Puente & Dana A Focks & Thomas W Scott & Alun L Lloyd & Fred Gould, 2009. "Skeeter Buster: A Stochastic, Spatially Explicit Modeling Tool for Studying Aedes aegypti Population Replacement and Population Suppression Strategies," PLOS Neglected Tropical Diseases, Public Library of Science, vol. 3(9), pages 1-18, September.
    2. Colince Kamdem & Caroline Fouet & Joachim Etouna & François-Xavier Etoa & Frédéric Simard & Nora J Besansky & Carlo Costantini, 2012. "Spatially Explicit Analyses of Anopheline Mosquitoes Indoor Resting Density: Implications for Malaria Control," PLOS ONE, Public Library of Science, vol. 7(2), pages 1-15, February.
    3. Anonymous, 1964. "World Health Organization," International Organization, Cambridge University Press, vol. 18(4), pages 859-870, October.
    4. D. L. Smith & J. Dushoff & R. W. Snow & S. I. Hay, 2005. "The entomological inoculation rate and Plasmodium falciparum infection in African children," Nature, Nature, vol. 438(7067), pages 492-495, November.
    5. Catherine Linard & Marius Gilbert & Robert W Snow & Abdisalan M Noor & Andrew J Tatem, 2012. "Population Distribution, Settlement Patterns and Accessibility across Africa in 2010," PLOS ONE, Public Library of Science, vol. 7(2), pages 1-8, February.
    6. Matthew Cairns & Arantxa Roca-Feltrer & Tini Garske & Anne L. Wilson & Diadier Diallo & Paul J. Milligan & Azra C Ghani & Brian M. Greenwood, 2012. "Estimating the potential public health impact of seasonal malaria chemoprevention in African children," Nature Communications, Nature, vol. 3(1), pages 1-9, January.
    7. Janet T. Midega & Dave L. Smith & Ally Olotu & Joseph M. Mwangangi & Joseph G. Nzovu & Juliana Wambua & George Nyangweso & Charles M. Mbogo & George K. Christophides & Kevin Marsh & Philip Bejon, 2012. "Wind direction and proximity to larval sites determines malaria risk in Kilifi District in Kenya," Nature Communications, Nature, vol. 3(1), pages 1-8, January.
    8. WHO-VMI Dengue Vaccine Modeling Group, 2012. "Assessing the Potential of a Candidate Dengue Vaccine with Mathematical Modeling," PLOS Neglected Tropical Diseases, Public Library of Science, vol. 6(3), pages 1-6, March.
    9. J. O. Lloyd-Smith & S. J. Schreiber & P. E. Kopp & W. M. Getz, 2005. "Superspreading and the effect of individual variation on disease emergence," Nature, Nature, vol. 438(7066), pages 355-359, November.
    10. Fredros O Okumu & Nicodem J Govella & Sarah J Moore & Nakul Chitnis & Gerry F Killeen, 2010. "Potential Benefits, Limitations and Target Product-Profiles of Odor-Baited Mosquito Traps for Malaria Control in Africa," PLOS ONE, Public Library of Science, vol. 5(7), pages 1-18, July.
    11. Bree Cummins & Ricardo Cortez & Ivo M Foppa & Justin Walbeck & James M Hyman, 2012. "A Spatial Model of Mosquito Host-Seeking Behavior," PLOS Computational Biology, Public Library of Science, vol. 8(5), pages 1-13, May.
    12. David L. Smith & Chris J. Drakeley & Christinah Chiyaka & Simon I. Hay, 2010. "A quantitative analysis of transmission efficiency versus intensity for malaria," Nature Communications, Nature, vol. 1(1), pages 1-9, December.
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    Cited by:

    1. Sean L Wu & Héctor M Sánchez C. & John M Henry & Daniel T Citron & Qian Zhang & Kelly Compton & Biyonka Liang & Amit Verma & Derek A T Cummings & Arnaud Le Menach & Thomas W Scott & Anne L Wilson & St, 2020. "Vector bionomics and vectorial capacity as emergent properties of mosquito behaviors and ecology," PLOS Computational Biology, Public Library of Science, vol. 16(4), pages 1-32, April.
    2. Lingcai Kong & Jinfeng Wang & Zhongjie Li & Shengjie Lai & Qiyong Liu & Haixia Wu & Weizhong Yang, 2018. "Modeling the Heterogeneity of Dengue Transmission in a City," IJERPH, MDPI, vol. 15(6), pages 1-21, May.
    3. Stephan Karl & Michael T White & George J Milne & David Gurarie & Simon I Hay & Alyssa E Barry & Ingrid Felger & Ivo Mueller, 2016. "Spatial Effects on the Multiplicity of Plasmodium falciparum Infections," PLOS ONE, Public Library of Science, vol. 11(10), pages 1-20, October.
    4. Wei Duan, 2021. "Matrix-Based Formulation of Heterogeneous Individual-Based Models of Infectious Diseases: Using SARS Epidemic as a Case Study," IJERPH, MDPI, vol. 18(11), pages 1-20, May.

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