Abstract
Heat exposure of a population is often estimated by applying temperatures from outdoor monitoring stations. However, this can lead to exposure misclassification if residents do not live close to the monitoring station and temperature varies over small spatial scales due to land use/built environment variability, or if residents generally spend more time indoors than outdoors. Here, we compare summertime temperatures measured inside 145 homes in low-income households in Baltimore city with temperatures from the National Weather Service weather station in Baltimore. There is a large variation in indoor temperatures, with daily-mean indoor temperatures varying from 10 °C lower to 10 °C higher than outdoor temperatures. Furthermore, there is only a weak association between the indoor and outdoor temperatures across all houses, indicating that the outdoor temperature is not a good predictor of the indoor temperature for the residences sampled. It is shown that much of the variation is due to differences in the availability of air conditioning (AC). Houses with central AC are generally cooler than outdoors (median difference of − 3.4 °C) while those with no AC are generally warmer (median difference of 1.4 °C). For the collection of houses with central or room AC, there is essentially no relationship between indoor and outdoor temperatures, but for the subset of houses with no AC, there is a weak relationship (correlation coefficient of 0.36). The results presented here suggest future epidemiological studies of indoor exposure to heat would benefit from information on the availability of AC within the population.
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Funding
This work was supported by funding from a JHU Environment, Energy, Sustainability and Health Institute seed grant, NIEHS grants R21ES024021 and P01ES018176, NIEHS and EPA grant P50ES015903, and EPA grant 83451001.
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P.N. Breysse is currently employed by the Centers for Disease Control and Prevention, and is serving in his personal capacity.
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Waugh, D.W., He, Z., Zaitchik, B. et al. Indoor heat exposure in Baltimore: does outdoor temperature matter?. Int J Biometeorol 65, 479–488 (2021). https://doi.org/10.1007/s00484-020-02036-2
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DOI: https://doi.org/10.1007/s00484-020-02036-2