Abstract
Projections of temperature-related mortality rely upon exposure-response relationships using recent data. Analyzing long historical data and trends may extend knowledge of past and present impacts that may provide additional insight and improve future scenarios. We collected daily mean temperatures and daily all-cause mortality for the period 1901–2013 for Stockholm County, Sweden, and calculated the total attributable fraction of mortality due to non-optimal temperatures and quantified the contribution of cold and heat. Total mortality attributable to non-optimal temperatures varied between periods and cold consistently had a larger impact on mortality than heat. Cold-related attributable fraction (AF) remained stable over time whereas heat-related AF decreased. AF on cold days remained stable over time, which may indicate that mortality during colder months may not decline as temperatures increase in the future. More research is needed to enhance estimates of burdens related to cold and heat in the future.
Avoid common mistakes on your manuscript.
Background
Over the course of the twentieth century, mean temperatures increased in Stockholm, Sweden (SMHI 2018). The observed trend is projected to continue over this century (Field 2012; Nikulin et al. 2011), making climate change a key challenge to be faced by health systems over course of this century.
Recently developed methods quantify attribution of mortality across the entire temperature distribution, defining non-optimal modest and extreme temperatures above and below the minimum mortality temperature (MMT) (Gasparrini and Leone 2014). Gasparrini et al. (2015) quantified mortality in 13 countries and found cold contributing to a larger attributable fraction (AF) than heat.
In light of the ongoing climate change, the numbers of studies aiming at quantifying future risks of temperature-related mortality, in particular due to heat, are growing (Huang et al. 2011; Hajat et al. 2014; Petkova et al. 2014). Recently, Gasparrini et al. (2017) projected temperature-related mortality risks at the end of the century in over 400 locations for several climate change scenarios; depending on geographical location, average excess mortality would increase under high emission scenarios. Projections of temperature-related mortality rely upon exposure-response relationships derived from recent observed data; however, using historical data may provide additional insight in these complex relationships.
The aim of the current study was to investigate if mortality attributable due to non-optimal temperatures changed across the twentieth century in Stockholm County, Sweden. By analyzing historical data and trends, we extend knowledge of past and present impacts of temperature on health, which may provide additional insight and improve future scenarios.
Methods
The dataset and methods used in the current study are described in more detail elsewhere. In short, we collected daily mean temperatures and daily all-cause mortality for the period 1901–2013 for Stockholm County, Sweden (Åström et al. 2013). The relationship between the daily mean temperature and mortality was investigated using a Poisson regression allowing for overdispersion, adjusting for day of week, pandemics, and public Swedish holidays as well as adjusting for long-time trends using a smooth function (natural cubic spline) with eight degrees of freedom per year. We used a distributed lag nonlinear model considering lag times of up to 21 days (14 days were considered in a sensitivity analysis) for six periods (1901–1919, 1920–1939, 1940–1959, 1960–1979, 1980–1999, 2000–2013). For each period, we calculated the total AF of mortality due to non-optimal temperatures and quantified the contribution of cold and heat below and above MMT. In addition, we investigated mortality due to modest and extreme low and high temperatures. Modest cold and heat mortality AFs were calculated from the period-specific MMT to the 2.5th/97.5th percentile, whereas extreme cold and heat mortality AFs were calculated for temperatures below the 2.5th and above the 97.5th percentile of temperature distribution (Gasparrini et al. 2015).
To investigate any potential trend over time in the AF estimates, we performed a weighted least square linear regression with the AF estimates as the dependent variable and time as the independent variable using weights that were equal to the inverse of the standard deviation.
R version 3.2.3 and package DLNM was used (Gasparrini 2011).
Results
Descriptive statistics of daily mortality and mean temperatures for the periods are presented in Supplementary Table 1. Total mortality attributable to non-optimal temperatures varied substantially between periods, ranging from 3.1% during 1960–1979 to 8.6% during 1920–1939. Cold consistently had a substantially larger impact on mortality than heat, by at least a factor of 2.5. Cold-related AF ranged between 2.8 and 7.9%, whereas heat-related AFs were for all but the first period below 1%. During all periods, modestly cold days contributed to the largest attributable fractions.
There was no apparent trend over time for the cold-related AF, while there was some evidence suggesting a downward trend for heat-related AF. The decline over time in heat-related AF was driven by a decline in AF on modestly hot days, such that mortality during the latter periods was almost non-existent (Fig. 1, Supplementary Table 2). Supplementary Table 3 presents results using lag times of 14 days (results did not change).
Attributable fractions due to non-optimal temperatures and estimates of trends over time presented with their 95% confidence intervals
Discussion
For all periods, mortality attributable to cold was higher than that of heat. Mortality on modestly cold days accounted for the majority of mortality attributed to non-optimal temperature, which is in line with other studies (Gasparrini et al. 2015; Vicedo-Cabrera et al. 2018; Lee et al. 2018).
The estimates of the total AF for the last two periods are higher than those reported previously for Stockholm: Gasparrini et al. (2015) quantified a total AF of 3.9%, with cold accounting for 3.7% and heat for 0.2% in the Greater Stockholm area for the period 1990–2002 (our estimates for the same time period were total AF, 4.73%, with 4.51% due to cold and 0.22% due to heat). The present study used data from the county of Stockholm, which includes less urbanized settings and more disperse socioeconomic status on both an individual and neighborhood level.
We find modest evidence suggesting heat-related AF to be declining over time and strong evidence of a declining trend over time related to extreme heat. From the 1960s and onwards, the AF on modestly hot days was basically zero, which may partially be explained by increasing MMT and changes in the temperature-mortality relationships over time. Our findings of declining heat AF over time are in line with a recent study of 305 locations in ten countries, where the authors reported declining heat-related AFs over time in seven countries (Vicedo-Cabrera et al. 2018). Furthermore, Lee et al. (2018) reported decreasing heat-related AF over time in Taiwan and Korea, whereas it increased in Japan.
We find no strong evidence of a declining trend over time in cold-related AF. Cold-related AF peaked at 7.9% during the 1920s and 1930s, with more recent estimates of around 5.5% during the two latest periods of investigation. The magnitudes of the cold-related AFs, as well as the stable trend over time, show some similarities to those reported by Vicedo-Cabrera et al. (2018), implying that trends in cold-related impacts remain unclear.
It may not be appropriate to assume that higher temperatures would increase the number of heat-related deaths and decrease the number of cold-related deaths, nor may it be appropriate to not account for adaptation, which is likely to offset some of future increases in temperature-related mortality, as evidence suggests MMT not to be a stationary measure over time (Åström et al. 2016; Todd and Valleron 2015).
For Stockholm, Sweden, absolute and relative MMT increased over the course of the twentieth century (Åström et al. 2016), while the effect of extreme temperatures on mortality decreased (Åström et al. 2013), suggesting partial adaptation to increasing temperatures. Decreasing effects of temperature on mortality over long-time periods have been reported elsewhere (Davis et al. 2003a, b, Sheridan et al. 2009, Carson et al. 2006; Ekamper et al. 2009). However, it remains inevitably difficult to separate adaptation and acclimatization to increasing temperatures from general societal improvements associated with development, such as standard of living and the quality and accessibility of health care facilities (Sellers and Ebi 2017).
Using historic data, we found that the AF on cold days remained stable over time, which suggests that mortality during the colder months may not simply decline as temperatures increase in the future. How winter mortality will continue to evolve will remain a difficult component in the projections of future temperature-related mortality (Ebi and Mills 2013), as evidence suggests winter mortality may modify heat-related mortality the following summer (Rocklöv et al. 2009; Stafoggia et al. 2009).
With ongoing climate warming and associated adaptive processes, the temperature-mortality relationships on both sides of MMT may change, with the magnitude and direction of change uncertain. More research is needed to enhance estimates of the burden related to cold and heat in the future.
Conclusion
There was substantial variation between periods over the course of 110 years in the percentage of deaths attributable to non-optimal temperatures in Stockholm County, Sweden. The majority of these deaths occurred during modestly cold days. The attributable fraction remained similar over time for cold and declined for heat.
References
Åström D, O, Forsberg B, Edvinsson S, Rocklöv J (2013) Acute fatal effects of short-lasting extreme temperatures in Stockholm, Sweden: evidence across a century of change. Epidemiology 24:820–829
Åström DO, Tornevi A, Ebi KL, Rocklöv J, Forsberg B (2016) Evolution of minimum mortality temperature in Stockholm, Sweden, 1901–2009. Environ Health Perspect (Online) 124:740
Carson C, Hajat S, Armstrong B, Wilkinson P (2006) Declining vulnerability to temperature-related mortality in London over the 20th century. Am J Epidemiol 164:77–84
Davis RE, Knappenberger PC, Novicoff WM, Michaels PJ (2003a) Decadal changes in summer mortality in US cities. Int J Biometeorol 47:166–175. https://doi.org/10.1007/s00484-003-0160-8
Davis RE, Knappenberger PC, Michaels PJ, Novicoff WM (2003b) Changing heat-related mortality in the United States. Environ Health Perspect 111(14):1712–1718
Ebi KL, Mills D (2013) Winter mortality in a warming climate: a reassessment. Wiley Interdiscip Rev Clim Chang 4:203–212
Ekamper P, Van Poppel F, van Duin C, Garssen J (2009) 150 years of temperature-related excess mortality in the Netherlands. Demogr Res 21:385–426
Field CB (2012) Managing the risks of extreme events and disasters to advance climate change adaptation: special report of the intergovernmental panel on climate change (Cambridge University Press)
Gasparrini A (2011) Distributed lag linear and non-linear models in R: the package dlnm. J Stat Softw 43:1
Gasparrini A, Leone M (2014) Attributable risk from distributed lag models. BMC Med Res Methodol 14:55
Gasparrini A, Guo Y, Hashizume M, Lavigne E, Zanobetti A, Schwartz J, Tobias A, Tong S, Rocklöv J, Forsberg B (2015) Mortality risk attributable to high and low ambient temperature: a multicountry observational study. Lancet
Gasparrini A, Guo Y, Sera F, Vicedo-Cabrera AM, Huber V, Tong S, Coelho M d SZS, Saldiva PHN, Lavigne E, Correa PM (2017) Projections of temperature-related excess mortality under climate change scenarios. Lancet Planet Health 1:e360–ee67
Hajat S, Vardoulakis S, Heaviside C, Eggen B (2014) Climate change effects on human health: projections of temperature-related mortality for the UK during the 2020s, 2050s and 2080s. J Epidemiol Community Health 68:641–648
Huang C, Barnett AG, Wang X, Vaneckova P, FitzGerald G, Tong S (2011) Projecting future heat-related mortality under climate change scenarios: a systematic review. Environ Health Perspect
Lee W, Choi HM, Kim D, Honda Y, Guo YLL, & Kim H (2018) Temporal changes in mortality attributed to heat extremes for 57 cities in Northeast Asia. Sci Total Environ 616:703–709
Nikulin G, Kjellström E, Hansson ULF, Strandberg G, Ullerstig A (2011) Evaluation and future projections of temperature, precipitation and wind extremes over Europe in an ensemble of regional climate simulations. Tellus A 63:41–55
Petkova EP, Bader DA, Brooke Anderson G, Horton RM, Knowlton K, Kinney PL (2014) Heat-related mortality in a warming climate: projections for 12 US cities. Int J Environ Res Public Health 11:11371–11383
Rocklöv J, Forsberg B, Meister K (2009) Winter mortality modifies the heat-mortality association the following summer. Eur Respir J 33:245–251
Sellers S, Ebi KL (2017) Climate change and health under the shared socioeconomic pathway framework. Int J Environ Res Public Health 15:3
Sheridan SC, Kalkstein AJ, Kalkstein LS (2009) Trends in heat-related mortality in the United States, 1975–2004. Nat Hazards 50:145–160. https://doi.org/10.1007/s11069-008-9327-2
Stafoggia M, Forastiere F, Michelozzi P, Perucci CA (2009) Summer temperature-related mortality: effect modification by previous winter mortality. Epidemiology 20:575–583
Swedish Meteorological and Hydrological Institute (2018). www.smhi.se accessed 2018–04
Todd N, Valleron A-J (2015) Space-time covariation of mortality with temperature: a systematic study of deaths in France, 1968–2009. Environ Health Perspect (Online) 123:659
Vicedo-Cabrera AM, Sera F, Guo Y, Chung Y, Arbuthnott K, Tong S, Tobias A, Lavigne E, Coelho M d SZS, Saldiva PHN (2018) A multi-country analysis on potential adaptive mechanisms to cold and heat in a changing climate. Environ Int 111:239–246
Author information
Daniel Oudin Åström conceived and designed the study, collected, analyzed, and interpreted the data, created figures and tables, and wrote the first version of the manuscript.
Kristie L Ebi helped interpreting the data and writing the manuscript.
Ana Maria Vicedo-Cabrera and Antonio Gasparrini helped performing statistical analyses, interpreting the data, and writing the manuscript.
All authors read and approved the final manuscript.
Funding
Antonio Gasparrini was supported by the Medical Research Council UK (Grant ID: MR/M022625/1).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Electronic supplementary material
ESM 1
(DOCX 21 kb)
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Oudin Åström, D., Ebi, K.L., Vicedo-Cabrera, A.M. et al. Investigating changes in mortality attributable to heat and cold in Stockholm, Sweden. Int J Biometeorol 62, 1777–1780 (2018). https://doi.org/10.1007/s00484-018-1556-9
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00484-018-1556-9