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The Distribution of Ocular Chlamydia Prevalence across Tanzanian Communities Where Trachoma Is Declining

Author

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  • Salman A Rahman
  • Sheila K West
  • Harran Mkocha
  • Beatriz Munoz
  • Travis C Porco
  • Jeremy D Keenan
  • Thomas M Lietman

Abstract

Background: Mathematical models predict an exponential distribution of infection prevalence across communities where a disease is disappearing. Trachoma control programs offer an opportunity to test this hypothesis, as the World Health Organization has targeted trachoma for elimination as a public health concern by the year 2020. Local programs may benefit if a single survey could reveal whether infection was headed towards elimination. Using data from a previously-published 2009 survey, we test the hypothesis that Chlamydia trachomatis prevalence across 75 Tanzanian communities where trachoma had been documented to be disappearing is exponentially distributed. Methods/Findings: We fit multiple continuous distributions to the Tanzanian data and found the exponential gave the best approximation. Model selection by Akaike Information Criteria (AICc) suggested the exponential distribution had the most parsimonious fit to the data. Those distributions which do not include the exponential as a special or limiting case had much lower likelihoods of fitting the observed data. 95% confidence intervals for shape parameter estimates of those distributions which do include the exponential as a special or limiting case were consistent with the exponential. Lastly, goodness-of-fit testing was unable to reject the hypothesis that the prevalence data came from an exponential distribution. Conclusions: Models correctly predict that infection prevalence across communities where a disease is disappearing is best described by an exponential distribution. In Tanzanian communities where local control efforts had reduced the clinical signs of trachoma by 80% over 10 years, an exponential distribution gave the best fit to prevalence data. An exponential distribution has a relatively heavy tail, thus occasional high-prevalence communities are to be expected even when infection is disappearing. A single cross-sectional survey may be able to reveal whether elimination efforts are on-track. Author Summary: Trachoma is the leading infectious cause of blindness and the World Health Organization plans to eliminate it as a public health concern worldwide by the year 2020. It can be difficult for local trachoma programs to assess whether disease is headed towards elimination in their area. Mathematical infectious disease models describe that when a disease disappears, its prevalence across communities in that area form an exponential distribution. However, this theorem has never been tested with field data. In this study, we take trachoma prevalence data from Tanzania, in an area where trachoma was known to be disappearing, and find that the prevalence forms an exponential distribution. The implications of this study could be applied to other infectious diseases to provide evidence that prevalence is headed towards elimination.

Suggested Citation

  • Salman A Rahman & Sheila K West & Harran Mkocha & Beatriz Munoz & Travis C Porco & Jeremy D Keenan & Thomas M Lietman, 2015. "The Distribution of Ocular Chlamydia Prevalence across Tanzanian Communities Where Trachoma Is Declining," PLOS Neglected Tropical Diseases, Public Library of Science, vol. 9(3), pages 1-8, March.
    • Handle: RePEc:plo:pntd00:0003682
    DOI: 10.1371/journal.pntd.0003682
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    References listed on IDEAS

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    1. Park, Sung Y. & Bera, Anil K., 2009. "Maximum entropy autoregressive conditional heteroskedasticity model," Journal of Econometrics, Elsevier, vol. 150(2), pages 219-230, June.
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