Is population structure sufficient to generate area-level inequalities in influenza rates? An examination using agent-based models
Authored by Supriya Kumar, Kaitlin Piper, David D Galloway, James L Hadler, John J Grefenstette
Date Published: 2015
DOI: 10.1186/s12889-015-2284-2
Sponsors:
United States National Institutes of Health (NIH)
Platforms:
Framework for Reconstructing Epidemiological Dynamics (FRED)
Model Documentation:
Other Narrative
Model Code URLs:
http://fred.publichealth.pitt.edu/
Abstract
Background: In New Haven County, CT (NHC), influenza hospitalization
rates have been shown to increase with census tract poverty in multiple
influenza seasons. Though multiple factors have been hypothesized to
cause these inequalities, including population structure, differential
vaccine uptake, and differential access to healthcare, the impact of
each in generating observed inequalities remains unknown. We can design
interventions targeting factors with the greatest explanatory power if
we quantify the proportion of observed inequalities that hypothesized
factors are able to generate. Here, we ask if population structure is
sufficient to generate the observed area-level inequalities in NHC. To
our knowledge, this is the first use of simulation models to examine the
causes of differential poverty-related influenza rates.
Methods: Using agent-based models with a census-informed, realistic
representation of household size, age-structure, population density in
NHC census tracts, and contact rates in workplaces, schools, households, and neighborhoods, we measured poverty-related differential influenza
attack rates over the course of an epidemic with a 23 \% overall
clinical attack rate. We examined the role of asthma prevalence rates as
well as individual contact rates and infection susceptibility in
generating observed area-level influenza inequalities.
Results: Simulated attack rates (AR) among adults increased with census
tract poverty level (F = 30.5; P < 0.001) in an epidemic caused by a
virus similar to A (H1N1) pdm09. We detected a steeper, earlier
influenza rate increase in high-poverty census tracts-a finding that we
corroborate with a temporal analysis of NHC surveillance data during the
2009 H1N1 pandemic. The ratio of the simulated adult AR in the
highest-to lowest-poverty tracts was 33 \% of the ratio observed in
surveillance data. Increasing individual contact rates in the
neighborhood did not increase simulated area-level inequalities. When we
modified individual susceptibility such that it was inversely
proportional to household income, inequalities in AR between high-and
low-poverty census tracts were comparable to those observed in reality.
Discussion: To our knowledge, this is the first study to use simulations
to probe the causes of observed inequalities in influenza disease
patterns. Knowledge of the causes and their relative explanatory power
will allow us to design interventions that have the greatest impact on
reducing inequalities.
Conclusion: Differential exposure due to population structure in our
realistic simulation model explains a third of the observed inequality.
Differential susceptibility to disease due to prevailing chronic
conditions, vaccine uptake, and smoking should be considered in future
models in order to quantify the role of additional factors in generating
influenza inequalities.
Tags
Vaccination
Seasonal influenza
United-states
Pandemic
influenza
Health-care
Impact
Socioeconomic-status
Acute respiratory illness
New-haven county
Psychological stress