Abstract
Background: Ambient temperature is an important determinant of malaria transmission and suitability, affecting the life-cycle of the Plasmodium parasite and Anopheles vector. Early models predicted a thermal malaria transmission optimum of 31 °C, later revised to 25 °C using experimental data from mosquito and parasite biology. However, the link between ambient temperature and human malaria incidence remains poorly resolved. Methods: To evaluate the relationship between ambient temperature and malaria risk, 5833 febrile children (<18 years-old) with an acute, non-localizing febrile illness were enrolled from four heterogenous outpatient clinic sites in Kenya (Chulaimbo, Kisumu, Msambweni and Ukunda). Thick and thin blood smears were evaluated for the presence of malaria parasites. Daily temperature estimates were obtained from land logger data, and rainfall from National Oceanic and Atmospheric Administration (NOAA)'s Africa Rainfall Climatology (ARC) data. Thirty-day mean temperature and 30-day cumulative rainfall were estimated and each lagged by 30 days, relative to the febrile visit. A generalized linear mixed model was used to assess relationships between malaria smear positivity and predictors including temperature, rainfall, age, sex, mosquito exposure and socioeconomic status. Results: Malaria smear positivity varied between 42-83% across four clinic sites in western and coastal Kenya, with highest smear positivity in the rural, western site. The temperature ranges were cooler in the western sites and warmer in the coastal sites. In multivariate analysis controlling for socioeconomic status, age, sex, rainfall and bednet use, malaria smear positivity peaked near 25 °C at all four sites, as predicted a priori from an ecological model. Conclusions: This study provides direct field evidence of a unimodal relationship between ambient temperature and human malaria incidence with a peak in malaria transmission occurring at lower temperatures than previously recognized clinically. This nonlinear relationship with an intermediate optimal temperature implies that future climate warming could expand malaria incidence in cooler, highland regions while decreasing incidence in already warm regions with average temperatures above 25 °C. These findings support efforts to further understand the nonlinear association between ambient temperature and vector-borne diseases to better allocate resources and respond to disease threats in a future, warmer world.
Original language | English |
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Article number | 288 |
Journal | Parasites and Vectors |
Volume | 12 |
Issue number | 1 |
DOIs | |
State | Published - Jun 6 2019 |
Externally published | Yes |
Funding
We gratefully acknowledge our collaborators, field teams, and all of the Kenyan children and caregivers who participated in this study. We also thank David Medeiros from the Stanford Geospatial Center for map assistance. DL and the overall study was funded by R01 AI102918. MS was supported by a T32 Epidemiology Training grant (T32 AI 52073-11 A1) and the Child Health Research Institute Stephen Bechtel Endowed Postdoctoral Fellowship. EM was supported by the National Science Foundation (DEB-1518681 and DEB- 1640780; https ://nsf.gov/), the Stanford Woods Institute for the Environment (https ://woods .stanf ord.edu/resea rch/envir onmen tal-ventu re-proje cts), and the Stanford Center for Innovation in Global Health (http://globa lheal th.stanf ord.edu/resea rch/seed-grant s.html).
Funders | Funder number |
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National Institute of Allergy and Infectious Diseases | R01AI102918 |
National Science Foundation | DEB-1518681, DEB-1640780 |
Keywords
- Climate
- Clinic-based surveillance
- Kenya
- Malaria