How to estimate exposure when studying the temperature-mortality relationship? A case study of the Paris area

Schaeffer, Laura; Crouy-Chanel, Perrine de; Wagner, Vérène; Desplat, Julien; Pascal, Mathilde

doi:10.1007/s00484-015-1006-x

Cited by 22 publications

(13 citation statements)

References 25 publications

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“…The siting of the meteorological stations used in this study may introduce some bias into the results, particularly because some of the stations are located in cities with a strong urban heat island effect (which impacts the diurnal temperature range) and/or one that has amplified over the study period (e.g., Chow et al 2012 ; Hondula et al 2012 ). We anticipate that any such bias would be small in light of other studies that have reported that temperature–mortality models using single meteorological stations perform just as well as those that incorporate multiple meteorological stations from different locations across urban areas ( Guo et al 2013 ; Schaeffer et al 2016 ). Additional research is required to understand how well airport observations correlate to actual temperatures experienced by urban residents (e.g., Bernhard et al 2015 ; Kuras et al 2015 ).…”

Section: Discussionmentioning

confidence: 95%

Temperature Observation Time and Type Influence Estimates of Heat-Related Mortality in Seven U.S. Cities

Davis

Hondula

Patel

2016

Environ Health Perspect

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Background:Extreme heat is a leading weather-related cause of mortality in the United States, but little guidance is available regarding how temperature variable selection impacts heat–mortality relationships.Objectives:We examined how the strength of the relationship between daily heat-related mortality and temperature varies as a function of temperature observation time, lag, and calculation method.Methods:Long time series of daily mortality counts and hourly temperature for seven U.S. cities with different climates were examined using a generalized additive model. The temperature effect was modeled separately for each hour of the day (with up to 3-day lags) along with different methods of calculating daily maximum, minimum, and mean temperature. We estimated the temperature effect on mortality for each variable by comparing the 99th versus 85th temperature percentiles, as determined from the annual time series.Results:In three northern cities (Boston, MA; Philadelphia, PA; and Seattle, WA) that appeared to have the greatest sensitivity to heat, hourly estimates were consistent with a diurnal pattern in the heat-mortality response, with strongest associations for afternoon or maximum temperature at lag 0 (day of death) or afternoon and evening of lag 1 (day before death). In warmer, southern cities, stronger associations were found with morning temperatures, but overall the relationships were weaker. The strongest temperature–mortality relationships were associated with maximum temperature, although mean temperature results were comparable.Conclusions:There were systematic and substantial differences in the association between temperature and mortality based on the time and type of temperature observation. Because the strongest hourly temperature–mortality relationships were not always found at times typically associated with daily maximum temperatures, temperature variables should be selected independently for each study location. In general, heat-mortality was more closely coupled to afternoon and maximum temperatures in most cities we examined, particularly those typically prone to heat-related mortality.Citation:Davis RE, Hondula DM, Patel AP. 2016. Temperature observation time and type influence estimates of heat-related mortality in seven U.S. cities. Environ Health Perspect 124:795–804; http://dx.doi.org/10.1289/ehp.1509946

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Section: Discussionmentioning

confidence: 95%

Temperature Observation Time and Type Influence Estimates of Heat-Related Mortality in Seven U.S. Cities

Davis

Hondula

Patel

2016

Environ Health Perspect

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“…Therefore the data collected from the HKO site should accurately reflect meteorological conditions and their variations in Hong Kong. Furthermore, use of a single monitoring station for weather variables is standard for this sort of study done in urban areas,50 and a study on the use of multiple measuring stations in a densely populated European city50 found that there was ‘no added value in taking into account data from multiple weather stations when estimating exposure in the Paris area’. Another potential limitation is that our data included some non-emergency hospital admissions.…”

Section: Discussionmentioning

confidence: 99%

The short-term association between asthma hospitalisations, ambient temperature, other meteorological factors and air pollutants in Hong Kong: a time-series study

Lam

Chan

et al. 2016

Thorax

137

130

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“…Several recent studies suggest that the magnitude of the temperature–mortality association is either similar 12 , 13 or larger 14 when assessed using spatially refined exposure estimates versus weather station measurements. However, these studies were conducted in relatively limited geographic areas, leaving open the question of whether their findings are specific to these locations or more broadly generalizable.…”

Section: Introductionmentioning

confidence: 99%

Comparison of temperature-mortality associations estimated with different exposure metrics

Weinberger

Spangler

Zanobetti

et al. 2019

Environmental Epidemiology

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Background: Studies of the short-term association between ambient temperature and mortality often use temperature observations from a single monitoring station, frequently located at the nearest airport, to represent the exposure of individuals living across large areas. Population-weighted temperature estimates constructed from gridded meteorological data may offer an opportunity to improve exposure assessment in locations where station observations do not fully capture the average exposure of the population of interest. Methods: We compared the association between daily mean temperature and mortality in each of 113 United States counties using (1) temperature observations from a single weather station and (2) population-weighted temperature estimates constructed from a gridded meteorological dataset. We used distributed lag nonlinear models to estimate the 21-day cumulative association between temperature and mortality in each county, 1987–2006, adjusting for seasonal and long-term trends, day of week, and holidays. Results: In the majority (73.4%) of counties, the relative risk of death on extremely hot days (99th percentile of weather station temperature) versus the minimum mortality temperature was larger when generated from the population-weighted estimates. In contrast, relative risks on extremely cold days (first percentile of weather station temperature) were often larger when generated from the weather station observations. In most counties, the difference in associations estimated from the two temperature metrics was small. Conclusions: In a large, multi-site analysis, temperature-mortality associations were largely similar when estimated from weather station observations versus population-weighted temperature estimates. However, spatially refined exposure data may be more appropriate for analyses seeking to elucidate local health effects.

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How to estimate exposure when studying the temperature-mortality relationship? A case study of the Paris area

Cited by 22 publications

References 25 publications

Temperature Observation Time and Type Influence Estimates of Heat-Related Mortality in Seven U.S. Cities

Temperature Observation Time and Type Influence Estimates of Heat-Related Mortality in Seven U.S. Cities

The short-term association between asthma hospitalisations, ambient temperature, other meteorological factors and air pollutants in Hong Kong: a time-series study

Comparison of temperature-mortality associations estimated with different exposure metrics

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