The impact of vaccination on human papillomavirus infection with disassortative geographical mixing: a two-patch modeling study

The impact of vaccination on human papillomavirus infection with disassortative geographical mixing: a two-patch modeling study

Human papillomavirus (HPV) infection can spread between regions. What is the impact of disassortative geographical mixing on the dynamics of HPV transmission? Vaccination is effective in preventing HPV infection. How to allocate HPV vaccines between genders within each region and between regions to...

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Bibliographic Details
Published in:Journal of mathematical biology Vol. 84; no. 6; p. 43
Main Authors: Gao, Shasha, Martcheva, Maia, Miao, Hongyu, Rong, Libin
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-05-2022
Springer Nature B.V
Subjects:
Applications of Mathematics
Disease transmission
Female
Gender
Human papillomavirus
Humans
Immunization
Infections
Male
Mathematical and Computational Biology
Mathematics
Mathematics and Statistics
Papillomavirus Infections - epidemiology
Papillomavirus Infections - prevention & control
Papillomavirus Vaccines
Patches (structures)
Population number
Prevalence
Reproduction (biology)
Sex
Sex ratio
Sexual Behavior
Vaccination
Vaccines
Vaccination strategy
Two-patch
92B05
37N25
34D20
Disassortative mixing
Two-sex
Dynamic model
HPV
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Summary:Human papillomavirus (HPV) infection can spread between regions. What is the impact of disassortative geographical mixing on the dynamics of HPV transmission? Vaccination is effective in preventing HPV infection. How to allocate HPV vaccines between genders within each region and between regions to reduce the total infection? Here we develop a two-patch two-sex model to address these questions. The control reproduction number R 0 under vaccination is obtained and shown to provide a critical threshold for disease elimination. Both analytical and numerical results reveal that disassortative geographical mixing does not affect R 0 and only has a minor impact on the disease prevalence in the total population given the vaccine uptake proportional to the population size for each gender in the two patches. When the vaccine uptake is not proportional to the population size, sexual mixing between the two patches can reduce R 0 and mitigate the consequence of disproportionate vaccine coverage. Using parameters calibrated from the data of a case study, we find that if the two patches have the same or similar sex ratios, allocating vaccines proportionally according to the new recruits in two patches and giving priority to the gender with a smaller recruit rate within each patch will bring the maximum benefit in reducing the total prevalence. We also show that a time-variable vaccination strategy between the two patches can further reduce the disease prevalence. This study provides some quantitative information that may help to develop vaccine distribution strategies in multiple regions with disassortative mixing.
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ISSN:0303-6812
1432-1416
DOI:10.1007/s00285-022-01745-z