Patterns of infectious disease in human populations result from complex interactions between the infectious agent, the disease host, and the environment in which host and agent interact. Many environmental factors influence infectious disease dynamics including characteristics of the natural and built environments and social systems. This dissertation focuses on key environmental factors associated with two timely infectious diseases in the United States (US): acute gastrointestinal illness (AGI) following overflow discharge from combined sewer systems (CSS) in Massachusetts (MA), and patterns of COVID-19 outcomes in relation to the spatial distribution of essential workers in MA.
CSS exist in over 700 municipalities in the US as well as cities in Canada, Europe, Asia, and Australasia. When heavy rainfall or snowmelt occurs, CSS discharge untreated or undertreated wastewater into nearby waterways in combined sewer overflow (CSO) events. The association between CSO events and health has been understudied, and critical gaps in knowledge remain, including which exposure pathway(s) may be most relevant in communities downstream of CSO releases, whether CSO events and precipitation are independently associated with AGI, and which subpopulations may be at greatest risk of developing AGI following CSO events.
The rapid spread and severity of COVID-19 disease led to widespread stay-at-home orders in the US beginning in March of 2020. In MA, only a designated set of essential businesses remained open during the stay-at-home orders (March through May 2020). During this period, essential workers who performed their duties in person were at higher risk of contracting COVID-19 than people who worked from home, but among essential workers, risk varied by industry- and worksite-specific factors. While differential risk of COVID-19 mortality and outbreaks are documented among essential workers, risk of COVID-19 infection among essential workers has been difficult to ascertain because occupation is frequently missing from state and federal COVID-19 surveillance efforts.
The overall objective of this dissertation is to assess the associations between these two infectious diseases in MA and key environmental factors that influence how pathogens and susceptible hosts interact. The relationship between CSO events and AGI was investigated in a geographic region of MA where sewage discharges impact a river that is both a drinking water source and recreational destination for hundreds of thousands of people. Statewide patterns of COVID-19 cases and deaths were evaluated in relation to relative representation of categories of essential workers in MA census tracts. This dissertation relies on health outcome data from administrative and surveillance datasets, all analyses employ ecologic study designs with individual-level data aggregated to small areas, and methods incorporating geospatial and temporal data are included in each study.
In Chapter 2, the association between extreme CSO events and AGI was assessed in MA municipalities bordering the CSO-impaired Merrimack River with a secondary analysis evaluating differences in the associations between CSO and AGI based on municipal drinking water source. In the 4-days following 95th percentile upstream CSO discharge events, the cumulative risk ratio (CRR) of AGI increased by 17% and CRR increased by 62% after 99th percentile CSO events. Stratification by drinking water source suggests that the association between CSO events and AGI is most pronounced among municipalities that do not have river-sourced drinking water, but there is elevated risk of AGI among all municipalities regardless of drinking water source following the largest CSO events. These findings suggest that CSO discharge volume is a critical factor in the association between CSO events and AGI, and that exposure to CSO discharge may occur through multiple pathways. Chapter 3 extends the work of Chapter 2 to an evaluation of the strength of the association between CSO events and AGI across subpopulations defined by age, sex, healthcare payer type, area-level social vulnerability, and drinking water source. The CRR of AGI was most pronounced among young people ages 5–19 and people living in areas of low social vulnerability relative to cumulative risk for the population as a whole. The results of this study suggest that the association between CSO events and AGI differs among subpopulations characterized by both physiological and social characteristics. In Chapter 4, categories of essential workers were defined from the broad set of essential occupations defined in the MA emergency response to COVID-19. The association between census-tract-resolution populations of essential worker categories and COVID-19 cases and deaths was evaluated, adjusting for multiple sociodemographic risk factors for COVID-19. Elevated COVID-19 case incidence was observed among census tracts with the highest populations of workers in construction, building maintenance, transportation, production, and public-facing sales and service occupations. Reduced case incidence was observed in tracts with the highest populations of essential workers able to work from home. These findings suggest that occupational composition of census tracts in MA may have influenced community-level COVID-19 transmission, possibly through spread from essential workers to those in their households and communities. Overall, the findings of this dissertation provide insight into the environmental factors associated AGI and COVID-19 in MA. In both cases, consideration of environmental factors provides opportunities to inform public health intervention measures for infectious diseases that are 1) influenced by climate change, and 2) symptomatic of globalization. / 2026-01-03T00:00:00Z
| Identifer | oai:union.ndltd.org:bu.edu/oai:open.bu.edu:2144/47901 |
| Date | 04 January 2024 |
| Creators | Haley, Bethany Marino |
| Contributors | Heiger-Bernays, Wendy J. |
| Source Sets | Boston University |
| Language | en_US |
| Detected Language | English |
| Type | Thesis/Dissertation |
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