Household water insecurity (HWI) can have far‐reaching consequences for human health and well‐being, yet little is known about how environmental seasonality contributes to HWI variation. Using a systematic literature review, we examined the following questions: (1) How does environmental seasonality affect HWI? and (2) How do the effects vary over time? We also highlighted strategic areas for future research. We conducted the search using Scopus, Web of Science, PubMed, ProQuest, and EBSCO Academic Search Complete, with an end search date of February 3, 2021; only English‐language studies were included. Articles were included in the review if analysis studied seasonal temperature, precipitation, or freshwater variation and individual or household experiences with household water adequacy, water reliability, water affordability, or water safety. Bias was evaluated via hand assessment, and articles of poor quality were excluded. Studies that focused on extreme weather events or water insecurity at community or watershed levels were omitted. We identified 67 articles, the majority of which were cross‐sectional (n = 46, 68.7%). Among longitudinal studies (n = 21, 31.3%), only one used a quantitative HWI scale, while the rest relied on proxies (n = 20, 95.2%). Our review also revealed literature gaps related to unequal coverage of freshwater ecosystem habitat types and forms of environmental seasonality. There is a need for more attention to extreme climate events, such as a prolonged multiyear drought. With changing climate expected to exacerbate weather patterns with serious implications, especially for vulnerable populations, understanding seasonality in HWI is important for crafting sustainable engineering and policy responses to water insecurity.
This article is categorized under:
Water and Life > Nature of Freshwater Ecosystems
Science of Water > Water and Environmental Change
Engineering Water > Sustainable Engineering of Water
Objectives. To investigate the effects of coal-fired power plant closures on zip code–level rates of emergency department visits for asthma-related conditions among 0- to 4-year-old children in Chicago, Illinois. Methods. We used data on wind, population, PM2.5 (particulates measuring ≤ 2.5 µm in diameter), and zip code–level rates of emergency department visits for asthma-related conditions among 0- to 4-year-old children between 2009 and 2017 in Chicago. The difference-in-differences research design compared rates of emergency department visits in zip codes near 3 coal-fired power plants before and after their closures to rates in zip codes farther away during the same time period. Results. We found that emergency department visits for asthma-related conditions among 0- to 4-year-old children decreased by 12% in zip codes near the 3 coal-fired power plants following their closures relative to rates in zip codes farther away during the same period. The crude and age-specific rates of emergency department visits decreased by 2.41 visits per ten thousand inhabitants and 35.63 visits per ten thousand children aged 0 to 4 years, respectively. Conclusions. Our findings demonstrate that closing coal-fired power plants can lead to improvements in the respiratory health of young children. (Am J Public Health. Published online ahead of print March 18, 2021: e1–e9. https://doi.org/10.2105/AJPH.2021.306155 )
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