Extreme weather events and dengue in Southeast Asia: a regionally-representative analysis of 291 locations from 1998 to 2021

  1. Sophearen Ith
  2. Xerxes Seposo
  3. Vitou Phy
  4. Kraichat Tantrakarnapa
  5. Geminn Louis C. Apostol
  6. Pandji Wibawa Dhewantara
  7. Rozita Hod
  8. Mohd Rohaizat Hassan
  9. Hidayatulfathi Othman
  10. Mazrura Sahani
  11. Jue Tao Lim
  12. Ha Hong Nhung
  13. Nguyen Hai Tuan
  14. Ngu Duy Nghia
  15. Taichiro Takemura
  16. Inthavong Nouhak
  17. Paul Lester Carlos Chua
  18. Alex R Cook
  19. Felipe J Colón-González
  20. Masahiro Hashizume
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Abstract

Background

Climate change, leading to more frequent and intense extreme weather events (EWEs), could significantly impact dengue transmission. However, the associations between EWEs and dengue remains underexplored in the Southeast Asia (SEA) region. We investigated the association between selected EWEs (i.e. heatwaves, extremely wet, and drought conditions) and dengue in the SEA region.

Methods and Findings

Monthly dengue case reports were obtained from 291 locations across eight SEA countries between 1998 and 2021. Heatwaves are defined as the monthly total number of days where temperatures exceed the 95th percentile for at least two consecutive days. Droughts and extremely wet conditions are defined by a self-calibrating Palmer Drought Severity Index (scPDSI). We implemented a generalized additive mixed model coupled with a distributed lag non-linear model to estimate the association between each EWE and dengue. Months with fewer than 12 heatwave days increased dengue risk with delayed effect after two months lag, compared with months without any heatwave. Highest dengue risk is at 7 heatwave days (RR=1·28; 95%CI: 1·19,1·38). Compared to normal conditions (i.e. scPDSI=0), drought conditions (i.e. scPDSI=–4) were positively associated with dengue risk (RR=1·85; 95%CI: 1·73,1·99), while extremely wet conditions (i.e. scPDSI=4) have reduced dengue risk (RR=0·89; 95%CI: 0·87,0·91). Although the findings of this study are significant, its limitations arise from the inconsistency of dengue case reporting, which might complicate dengue risk estimation.

Conclusions

This study shows that the delayed effect of heatwaves and drought conditions magnifies the risk of dengue in the SEA region. Our findings offer stakeholders sizeable amount of time to organize and implement public health interventions in minimizing the prospective dengue risk, posed by EWEs in the context of climate change in SEA. Future research may focus on factors associated with dengue risk variations within SEA region to facilitate the development of location-based, tailor-fit mitigation and preventative interventions.

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  1. Version published to 10.1101/2024.10.24.24316055v1 on medRxiv