PLoS Computational Biology (Jun 2022)

Characterizing superspreading potential of infectious disease: Decomposition of individual transmissibility.

  • Shi Zhao,
  • Marc K C Chong,
  • Sukhyun Ryu,
  • Zihao Guo,
  • Mu He,
  • Boqiang Chen,
  • Salihu S Musa,
  • Jingxuan Wang,
  • Yushan Wu,
  • Daihai He,
  • Maggie H Wang

DOI
https://doi.org/10.1371/journal.pcbi.1010281
Journal volume & issue
Vol. 18, no. 6
p. e1010281

Abstract

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In the context of infectious disease transmission, high heterogeneity in individual infectiousness indicates that a few index cases can generate large numbers of secondary cases, a phenomenon commonly known as superspreading. The potential of disease superspreading can be characterized by describing the distribution of secondary cases (of each seed case) as a negative binomial (NB) distribution with the dispersion parameter, k. Based on the feature of NB distribution, there must be a proportion of individuals with individual reproduction number of almost 0, which appears restricted and unrealistic. To overcome this limitation, we generalized the compound structure of a Poisson rate and included an additional parameter, and divided the reproduction number into independent and additive fixed and variable components. Then, the secondary cases followed a Delaporte distribution. We demonstrated that the Delaporte distribution was important for understanding the characteristics of disease transmission, which generated new insights distinct from the NB model. By using real-world dataset, the Delaporte distribution provides improvements in describing the distributions of COVID-19 and SARS cases compared to the NB distribution. The model selection yielded increasing statistical power with larger sample sizes as well as conservative type I error in detecting the improvement in fitting with the likelihood ratio (LR) test. Numerical simulation revealed that the control strategy-making process may benefit from monitoring the transmission characteristics under the Delaporte framework. Our findings highlighted that for the COVID-19 pandemic, population-wide interventions may control disease transmission on a general scale before recommending the high-risk-specific control strategies.