Searching for the best modeling specification for assessing the effects of temperature and humidity on health: a time series analysis in three European cities

Epidemiological time series studies suggest daily temperature and humidity are associated with adverse health effects including increased mortality and hospital admissions. However, there is no consensus over which metric or lag best describes the relationships. We investigated which temperature and...

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Bibliographic Details
Published in:International journal of biometeorology 2015-11, Vol.59 (11), p.1585-1596
Main Authors: Rodopoulou, Sophia, Samoli, Evangelia, Analitis, Antonis, Atkinson, Richard W., de’Donato, Francesca K., Katsouyanni, Klea
Format: Article
Language:English
Subjects:
Air pollution
Animal Physiology
Biological and Medical Physics
Biophysics
Cities
Cities - epidemiology
Climate
Dew point
Earth and Environmental Science
England - epidemiology
Environment
Environmental Health
Epidemiology
Greece - epidemiology
Health risks
Humans
Humidity
Italy - epidemiology
Meteorology
Models, Theoretical
Mortality
Original Paper
Plant Physiology
Public health
Relative humidity
Seasonal variations
Temperature
Temperature effects
Time series
Warning systems
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Summary:Epidemiological time series studies suggest daily temperature and humidity are associated with adverse health effects including increased mortality and hospital admissions. However, there is no consensus over which metric or lag best describes the relationships. We investigated which temperature and humidity model specification most adequately predicted mortality in three large European cities. Daily counts of all-cause mortality, minimum, maximum and mean temperature and relative humidity and apparent temperature (a composite measure of ambient and dew point temperature) were assembled for Athens, London, and Rome for 6 years between 1999 and 2005. City-specific Poisson regression models were fitted separately for warm (April–September) and cold (October–March) periods adjusting for seasonality, air pollution, and public holidays. We investigated goodness of model fit for each metric for delayed effects up to 13 days using three model fit criteria: sum of the partial autocorrelation function, AIC, and GCV. No uniformly best index for all cities and seasonal periods was observed. The effects of temperature were uniformly shown to be more prolonged during cold periods and the majority of models suggested separate temperature and humidity variables performed better than apparent temperature in predicting mortality. Our study suggests that the nature of the effects of temperature and humidity on mortality vary between cities for unknown reasons which require further investigation but may relate to city-specific population, socioeconomic, and environmental characteristics. This may have consequences on epidemiological studies and local temperature-related warning systems.
ISSN:0020-7128
1432-1254
DOI:10.1007/s00484-015-0965-2