The Impact of Realistic Age Structure in Simple Models of Tuberculosis Transmission
Authored by Ellen Brooks-Pollock, Ted Cohen, Megan Murray
Date Published: 2010
DOI: 10.1371/journal.pone.0008479
Sponsors:
United States National Institutes of Health (NIH)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Background: Mathematical models of tuberculosis (TB) transmission have
been used to characterize disease dynamics, investigate the potential
effects of public health interventions, and prioritize control measures.
While previous work has addressed the mathematical description of TB
natural history, the impact of demography on the behaviour of TB models
has not been assessed.
Methods: A simple model of TB transmission, with alternative assumptions
about survivorship, is used to explore the effect of age structure on
the prevalence of infection, disease, basic reproductive ratio and the
projected impact of control interventions. We focus our analytic
arguments on the differences between constant and exponentially
distributed lifespans and use an individual-based model to investigate
the range of behaviour arising from realistic distributions of
survivorship.
Results: The choice of age structure and natural (non-disease related)
mortality strongly affects steady-state dynamics, parameter estimation
and predictions about the effectiveness of control interventions. Since
most individuals infected with TB develop an asymptomatic latent
infection and never progress to active disease, we find that assuming a
constant mortality rate results in a larger reproductive ratio and an
overestimation of the effort required for disease control in comparison
to using more realistic age-specific mortality rates.
Conclusions: Demographic modelling assumptions should be considered in
the interpretation of models of chronic infectious diseases such as TB.
For simple models, we find that assuming constant lifetimes, rather than
exponential lifetimes, produces dynamics more representative of models
with realistic age structure.
Tags
Dynamics
patterns
Distributions
Populations
Mycobacterium-tuberculosis
Infectious-diseases
Epidemic models
Persistence
Risks
Drug-resistant tuberculosis