Modeling HIV outbreaks: The male to female prevalence ratio in the core population
What affects the ratio of infected men to infected women in the core population in a heterosexual HIV epidemic? Hethcote & Yorke [5] introduced the term 'core' initially to loosely describe the collection of individuals having the most unprotected sex partners. We study the early epid...
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AIMS Press
2008-11-01
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| Series: | Mathematical Biosciences and Engineering |
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| Online Access: | https://www.aimspress.com/article/doi/10.3934/mbe.2009.6.135 |
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| author | Brandy Rapatski James Yorke |
| author_facet | Brandy Rapatski James Yorke |
| author_sort | Brandy Rapatski |
| collection | DOAJ |
| description | What affects the ratio of infected men to infected women in the core population in a heterosexual HIV epidemic? Hethcote & Yorke [5] introduced the term 'core' initially to loosely describe the collection of individuals having the most unprotected sex partners. We study the early epidemic during the exponential growth phase and focus on the core group because most infected people were infected by people in the core. We argue that in the early outbreak phase of an epidemic, there is an identity, which we call the 'outbreak equation.' It relates three ratios that describe the core men versus the core women, namely, the ratio $E$ of numbers of all core men to all core women, the ratio $C$ of numbers of infected core men to core women, and the ratio $M$ of the infectiousness of a typical core man to that of a typical core woman. Then the relationship between the ratios is $E=MC^2$ in the early outbreak phase. We investigate two very different scenarios, one in which there are two times as many core men as core women ($E=2$) and the other in which core men equal core women ($E=1$). In the first case, the HIV epidemic grows at a much faster rate. We conclude that if the female core group was larger, that is, if more women in the total population were promiscuous (or if fewer men were promiscuous) then the HIV epidemic would grow more slowly. |
| format | Article |
| id | doaj-art-f5eab8b10bb046e6a2a0e685cfd5b3f4 |
| institution | Kabale University |
| issn | 1551-0018 |
| language | English |
| publishDate | 2008-11-01 |
| publisher | AIMS Press |
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| series | Mathematical Biosciences and Engineering |
| spelling | doaj-art-f5eab8b10bb046e6a2a0e685cfd5b3f42025-01-24T01:58:53ZengAIMS PressMathematical Biosciences and Engineering1551-00182008-11-016113514310.3934/mbe.2009.6.135Modeling HIV outbreaks: The male to female prevalence ratio in the core populationBrandy Rapatski0James Yorke1Department of Mathematics, Richard Stockton College of New Jersey, Pomona, NJ 08240Department of Mathematics, Richard Stockton College of New Jersey, Pomona, NJ 08240What affects the ratio of infected men to infected women in the core population in a heterosexual HIV epidemic? Hethcote & Yorke [5] introduced the term 'core' initially to loosely describe the collection of individuals having the most unprotected sex partners. We study the early epidemic during the exponential growth phase and focus on the core group because most infected people were infected by people in the core. We argue that in the early outbreak phase of an epidemic, there is an identity, which we call the 'outbreak equation.' It relates three ratios that describe the core men versus the core women, namely, the ratio $E$ of numbers of all core men to all core women, the ratio $C$ of numbers of infected core men to core women, and the ratio $M$ of the infectiousness of a typical core man to that of a typical core woman. Then the relationship between the ratios is $E=MC^2$ in the early outbreak phase. We investigate two very different scenarios, one in which there are two times as many core men as core women ($E=2$) and the other in which core men equal core women ($E=1$). In the first case, the HIV epidemic grows at a much faster rate. We conclude that if the female core group was larger, that is, if more women in the total population were promiscuous (or if fewer men were promiscuous) then the HIV epidemic would grow more slowly.https://www.aimspress.com/article/doi/10.3934/mbe.2009.6.135effective contact rateinfectiousnesshuman immunodeficiency viruscore populationinfectiousness multiplier |
| spellingShingle | Brandy Rapatski James Yorke Modeling HIV outbreaks: The male to female prevalence ratio in the core population Mathematical Biosciences and Engineering effective contact rate infectiousness human immunodeficiency virus core population infectiousness multiplier |
| title | Modeling HIV outbreaks: The male to female prevalence ratio in the core population |
| title_full | Modeling HIV outbreaks: The male to female prevalence ratio in the core population |
| title_fullStr | Modeling HIV outbreaks: The male to female prevalence ratio in the core population |
| title_full_unstemmed | Modeling HIV outbreaks: The male to female prevalence ratio in the core population |
| title_short | Modeling HIV outbreaks: The male to female prevalence ratio in the core population |
| title_sort | modeling hiv outbreaks the male to female prevalence ratio in the core population |
| topic | effective contact rate infectiousness human immunodeficiency virus core population infectiousness multiplier |
| url | https://www.aimspress.com/article/doi/10.3934/mbe.2009.6.135 |
| work_keys_str_mv | AT brandyrapatski modelinghivoutbreaksthemaletofemaleprevalenceratiointhecorepopulation AT jamesyorke modelinghivoutbreaksthemaletofemaleprevalenceratiointhecorepopulation |