Effects of Mitigation and Control Policies in Realistic Epidemic Models Accounting for Household Transmission Dynamics

We formulated an approach that incorporates household structure into ID models, extending the work of House and Keeling.

Bias
Differential Equations
Household transmission
Infectious diseases
Mathematical Epidemiology
Multicompartment Structure
Uncertainty quantification
Value of information (VOI)
Authors

Alarid-Escudero, F.

Andrews, J. R.

Goldhaber-Fiebert, J. D.

Published

November 13, 2023

Recommended citation

Alarid-Escudero, F., Andrews, J. R., & Goldhaber-Fiebert, J. D. (2024). Effects of Mitigation and Control Policies in Realistic Epidemic Models Accounting for Household Transmission Dynamics. Medical Decision Making, 44(1), 5-17.

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@article{alarid2024effects,
  title={Effects of Mitigation and Control Policies in Realistic Epidemic Models Accounting for Household Transmission Dynamics},
  author={Alarid-Escudero, Fernando and Andrews, Jason R and Goldhaber-Fiebert, Jeremy D},
  journal={Medical Decision Making},
  volume={44},
  number={1},
  pages={5--17},
  year={2024},
  publisher={SAGE Publications Sage CA: Los Angeles, CA}
}

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%0 Journal Article
%T Effects of Mitigation and Control Policies in Realistic Epidemic Models Accounting for Household Transmission Dynamics
%A Alarid-Escudero, Fernando
%A Andrews, Jason R
%A Goldhaber-Fiebert, Jeremy D
%J Medical Decision Making
%V 44
%N 1
%P 5-17
%@ 0272-989X
%D 2024
%I SAGE Publications Sage CA: Los Angeles, CA

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TY  - JOUR
T1  - Effects of Mitigation and Control Policies in Realistic Epidemic Models Accounting for Household Transmission Dynamics
A1  - Alarid-Escudero, Fernando
A1  - Andrews, Jason R
A1  - Goldhaber-Fiebert, Jeremy D
JO  - Medical Decision Making
VL  - 44
IS  - 1
SP  - 5
EP  - 17
SN  - 0272-989X
Y1  - 2024
PB  - SAGE Publications Sage CA: Los Angeles, CA
ER  -

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Abstract

 

Background

Compartmental infectious disease (ID) models are often used to evaluate nonpharmaceutical interventions (NPIs) and vaccines. Such models rarely separate within-household and community transmission, potentially introducing biases in situations in which multiple transmission routes exist. We formulated an approach that incorporates household structure into ID models, extending the work of House and Keeling.

Design

We developed a multicompartment susceptible-exposed-infectious-recovered-susceptible-vaccinated (MC-SEIRSV) modeling framework, allowing nonexponentially distributed duration in exposed and infectious compartments, that tracks within-household and community transmission. We simulated epidemics that varied by community and household transmission rates, waning immunity rate, household size (3 or 5 members), and numbers of exposed and infectious compartments (1–3 each). We calibrated otherwise identical models without household structure to the early phase of each parameter combination’s epidemic curve. We compared each model pair in terms of epidemic forecasts and predicted NPI and vaccine impacts on the timing and magnitude of the epidemic peak and its total size. Meta-analytic regressions characterized the relationship between household structure inclusion and the size and direction of biases.

Results

Otherwise similar models with and without household structure produced equivalent early epidemic curves. However, forecasts from models without household structure were biased. Without intervention, they were upward biased on peak size and total epidemic size, with biases also depending on the number of exposed and infectious compartments. Model-estimated NPI effects of a 60% reduction in community contacts on peak time and size were systematically overestimated without household structure. Biases were smaller with a 20% reduction NPI. Because vaccination affected both community and household transmission, their biases were smaller.