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Insights into COVID-19 epidemiology and control from temporal changes in serial interval distributions in Hong Kong.

Sheikh Taslim AliDongxuan ChenYiu-Chung LauWey Wen LimAmy YeungDillon C AdamEric H Y LauJessica Y WongJingyi XiaoFaith HoHuizhi GaoLin WangXiao-Ke XuZhanwei DuPeng WuGabriel M LeungBenjamin John Cowling
Published in: American journal of epidemiology (2024)
The serial interval distribution is used to approximate the generation time distribution, an essential parameter to infer the transmissibility (${R}_t$) of an epidemic. However, serial interval distributions may change as an epidemic progresses. We examined detailed contact tracing data on laboratory-confirmed cases of COVID-19 in Hong Kong during the five waves from January 2020 to July 2022. We reconstructed the transmission pairs and estimated time-varying effective serial interval distributions and factors associated with longer or shorter intervals. Finally, we assessed the biases in estimating transmissibility using constant serial interval distributions. We found clear temporal changes in mean serial interval estimates within each epidemic wave studied and across waves, with mean serial intervals ranged from 5.5 days (95% CrI: 4.4, 6.6) to 2.7 (95% CrI: 2.2, 3.2) days. The mean serial intervals shortened or lengthened over time, which were found to be closely associated with the temporal variation in COVID-19 case profiles and public health and social measures and could lead to the biases in predicting ${R}_t$. Accounting for the impact of these factors, the time-varying quantification of serial interval distributions could lead to improved estimation of ${R}_t$, and provide additional insights into the impact of public health measures on transmission.
Keyphrases
  • public health
  • coronavirus disease
  • sars cov
  • healthcare
  • machine learning
  • monte carlo
  • respiratory syndrome coronavirus
  • artificial intelligence