Importance of Housing and Cardiovascular Health and Well-Being: A Scientific Statement From the American Heart Association


Cardiovascular disease (CVD) disparities are shaped by differences in risk factors across racial/ethnic and socioeconomic groups. Disparities have been noted largely by differences in risk factors for CVD (hypertension, diabetes mellitus, obesity, cholesterol), cardiovascular incidence, and mortality.1 Recently, more attention has focused on the social determinants of cardiovascular risk and outcomes.2 Vulnerable and underserved populations (eg, blacks) report greater levels of psychosocial stress, which is associated with racial disparities in risk factors such as hypertension and obesity.3 Where one lives remains an important social determinant of health (SDH) as well. Studies have examined primarily the associations of residential environments with CVD risk.4 However, the conditions of housing (ie, stability, quality, affordability) are also important contributors to existing health inequities.5

The SDH conceptual framework emphasizes how social structures affect population health through myriad social, economic, political, psychosocial, and behavioral interactions.6 Structural mechanisms (ie, socioeconomic and political context and social class divisions) generate social hierarchies that influence intermediary determinants of health (ie, behaviors, psychosocial factors, and material circumstances), which ultimately affect health inequity and well-being. This statement focuses on the segment of the SDH framework that addresses pathways between living/housing conditions and cardiovascular health.7 Although outside of the scope of this review, we recognize that racial and socioeconomic disadvantages are shaped by upstream social structures that affect economic resources available to purchase housing status, which ultimately may affect downstream cardiovascular health and well-being.

This statement considers 4 major pathways connecting housing and cardiovascular health: housing stability, housing quality and safety, housing affordability and accessibility, and neighborhood physical and social environment. Using previous work on housing and health,8–11 Taylor12 summarized their health impact and implications for SDH (Figure). The objective of this statement is to review and summarize research that has examined the pathways linking housing to cardiovascular health and overall health. The following approach was used to identify empirical studies that examined housing and cardiovascular health and well-being: We used PubMed/Medline, Centers for Disease Control and Prevention data, US Census data, Cochrane Library reviews database, and the annual Heart Disease and Stroke Statistics report from the American Heart Association; performed key word searches on residential stability, quality and safety, affordability and accessibility, neighborhood environment, CVD, and cardiovascular and overall health; and limited the search to studies published in the past 20 years. An understanding of these dimensions of housing is important for reducing and ultimately eliminating the health inequities that plague vulnerable and underserved populations.

Figure.

Figure. Four pathways connecting housing and health. Adapted from Taylor12 with permission of Project Hope/Health Affairs Journal; permission conveyed through Copyright Clearance Center, Inc. Copyright © 2018, Project HOPE—The People-to-People Health Foundation, Inc. Data derived from the work of Braveman et al,8 Gibson et al,9 Maqbool et al,10 and Sandel et al.11

Housing Stability

Indicators of housing instability such as homelessness and housing insecurity are associated with poor physical and mental health outcomes. Homelessness is defined by the US Department of Housing and Urban Development as not having the resources to obtain permanent housing. Categories of homelessness include frequent moves in a short period of time (eg, serial renters), temporary shelter in a hotel, living with friends (couching surfing), or staying in a shelter and unsheltered situations (eg, on the street).13,14 National data on homelessness report that 7% of people without permanent housing live in rural areas,15 which has health implications for urban versus rural homelessness.

Epidemiological data suggest that adults who are homeless experience 60% to 70% higher rates of cardiovascular events compared with the general population.16,17 In terms of cardiovascular risk factors, data on homeless populations are mixed. Some studies have observed a similar prevalence of hypertension between homeless and nonhomeless adults,16 whereas others have observed higher rates of hypertension among homeless adults.17 The prevalence of diabetes mellitus in homeless adults appears to be similar to that in the general population. In contrast, prevalent cigarette smoking among homeless adults is high; between 70% and 80% of the population reported current smoking.16 Few studies have examined CVD risk assessments and homelessness.

In addition, nontraditional factors may contribute to an increased risk for CVD among certain subgroups of homeless individuals. Some studies have observed a higher prevalence of HIV, which may contribute to an elevated risk for CVD among some subgroups of homeless adults. An estimated 25% of homeless adults report recent cocaine use, which is associated with an increased risk for cardiovascular events, including myocardial infarction.16 The rate of mental illness is estimated to be 25% of the homeless population,16 which may be an additional factor contributing to fragmented CVD care in this population.

Homeless adults may experience a higher CVD mortality as a result of the inadequacy of cardiovascular risk factor diagnosis and treatment.16 Similarly, timely diagnosis of CVD may be difficult in this population because of barriers to care, need for testing sometimes over several days, medication initiation and adherence, and access to healthy foods. Issues of fragmented care and stigmatization in traditional healthcare settings may also contribute to inadequate treatment for cardiovascular risk factors and CVD management. However, data on the management of primary and secondary prevention of CVD are not well studied.

For those who confront housing insecurity (eg, high housing cost relative to income), the prevalence of cardiovascular risk factors may be higher than for those with more secure housing. Housing security has generally been based on self-reported difficulty paying rent or a mortgage. The 2015 Behavioral Risk Factor Surveillance System found that those with self-reported CVD were more likely to be housing insecure than those who did not have CVD.18 Those authors posited that developing CVD led to housing insecurity, but because this study is cross-sectional, the direction of this relationship is not clear. A study of Behavioral Risk Factor Surveillance System participants in Hawaii found that housing insecurity was associated with CVD and diabetes mellitus in Native Hawaiian and other Pacific Islanders but not among whites or Asians.19 In addition, a study of residents of the Philadelphia metropolitan area did not find a significant association between housing insecurity and self-reported heart disease, but it did find that housing-insecure participants were more likely to have hypertension.20

Housing security was unrelated to emergency department visits (for any reason) in the Philadelphia study,20 but a study of participants of the National Survey of American Families found that those who are housing insecure have more emergency department visits and hospitalizations.21 Two national studies found that housing-insecure participants were less likely to have a usual source of care,21,22 and studies in Philadelphia and Washington State found that housing-insecure participants were less likely to seek medical care or prescription medications because of cost.20 A review reported that those at risk for home eviction were more likely to have negative health outcomes, including depression, poor self-reported health, and elevated blood pressure.23 Among 711 low-income adults with diabetes mellitus, housing instability (adults lacking a usual place to stay) was inversely associated with self-efficacy for diabetes mellitus self-care.24

Several barriers to cardiovascular care may be particularly prevalent among the homeless or those with housing insecurity. Competing stressors include the need to obtain nightly shelter, food, and clothing. Suboptimal sleep is likely to be common among the homeless. Given recent evidence for the association of poor sleep with cardiovascular risk, this may be an important modifiable factor for this population.25 Barriers to obtaining regular care, lack of insurance, and barriers to obtaining and storing medications may be more prevalent among the homeless population. Housing instability was associated with postponing medical care and medications, increased use of the emergency department, and a higher rate of hospitalizations.21 Housing instability was also inversely associated with access to a usual source of health care. Last, prediction tools such as the Pooled Risk Equation may not adequately represent the homeless population given the lack of nontraditional risk factors incorporated into such risk prediction tools. In addition to reducing knowledge gaps related to the epidemiology of cardiovascular risk factors and CVD among homeless or housing-insecure adults throughout the United States, data on tailored medical management of primary and secondary CVD are required to improve cardiovascular health care in these populations. Last, because 2015 data suggest that rental options are limited in rural areas,26 which has health implications for housing insecurity between urban and rural poor residents, more research is needed that examines these area differences in housing stability.

Overall, our measures of instability considered the negative cardiovascular health consequences of homelessness and insecurity. Housing instability describes conditions that stem from involuntary moves. Conversely, voluntary moves are characterized by residential mobility, which may yield positive or negative health consequences (peace of mind or anxiety of a new environment, respectively). We have demonstrated that housing instability is long term and less likely to have a positive impact on health.

Housing Quality and Safety

Poor housing quality has been associated with numerous physical and mental health conditions.27 In addition, residential crowding has been associated with poor health outcomes among both children and adults, but little is known about the impact of poor housing quality on cardiovascular health. Features of housing quality such as structural deterioration, presence of mold and pests, lead, insufficient heating/cooling, and poor air quality (tobacco smoke) have been associated with mental health, behaviors, and other physical health conditions.5 In addition to the health impact, poor housing quality can lead to an unsafe environment. Dilapidated and deteriorated housing can lead to increased risk of falls and injuries; nonworking smoke detectors or faulty electric systems can lead to power outages and fires, increasing the risk of injury and even death.28 Low-income housing, including public housing, is often of poorer quality because the physical residences may be older and in need of repairs and service maintenance, which often are not conducted on a consistent basis. Renovations and modifications to housing can improve certain features of the housing environment and consequently influence health outcomes. Housing options in rural areas are often poorer quality than in urban areas; a substantial proportion of rural homes have inadequate heating or plumbing systems, leaks, or pests.29 This level of substandard housing likely affects the health of rural residents.

Housing quality factors have been shown to affect a number of health outcomes among both children and adults. However, little is known about the impact of housing quality and safety on cardiovascular health. Extensive literature has shown that air pollutants, specifically particulate matter and elemental carbon, are associated with CVD and mortality.30 These pollutants can be found in indoor residential environments as a result of using biomass, wood, and kerosene stoves and having tighter building construction and poor air ventilation systems.31 In addition, secondhand smoke exposure is highly prevalent among residents in multiunit housing and public housing, and secondhand tobacco smoke can migrate through shared ventilation systems, unsealed cracks, and door spaces, leading to adverse health outcomes.32 Although many low-income families turn to “doubling up” and overcrowding as a cost-saving coping strategy, this too may contribute to adverse health outcomes among both children and adults.

It is plausible that poor housing quality affects cardiovascular health as a result of cardiotoxic pollutants found in indoor air, environmental smoke, and volatile organic compounds. Poor housing quality also has been shown to affect mental health, which in turn is associated with cardiovascular health in both children and adults. The adverse psychological consequences of poor housing quality have been attributed partly to stress about substandard living conditions, poor control over the conditions of one’s home resulting from the inability to pay for upgrades, or housing tenure status as a renter, or all three.33

Those who live in older housing and people who live in public or low-income housing are more likely to have CVD. For example, NHANES (National Health and Nutrition Examination Survey) participants who reside in older housing (>20 years old) are more likely to self-report having had a stroke or heart failure and to have higher environmental contaminant concentrations as measured in blood and urine compared with those who reside in newer housing.34 In the AHOME study (Affordable Housing as an Obesity Mediating Environment), public housing residents in Bronx, NY, were more likely to self-report a heart attack or stroke and to have higher measured blood pressure compared with Section 8 housing residents and those who qualify for but do not receive housing assistance.35 There is a need to further examine how housing conditions may affect the cardiometabolic risk factors that contribute to the development of CVD.

Recently, several studies have evaluated the impact of interventions or remediation to evaluate the potential benefit of improving housing conditions. A 2013 systematic review of studies focusing on warmth and energy efficiency interventions, for example, concluded that investing in better thermal comfort can improve general health, respiratory health, and mental health.36 Improving housing thermal quality by reducing mold and dampness and producing a comfortable temperature have been shown to reduce systolic and diastolic blood pressures.37 Other home interventions targeting the improvement of air quality have been shown to reduce residential exposure to indoor air pollutants; however, whether the improvements in air quality affect cardiovascular health is largely unknown.

Overall, limited literature examines factors that relate to housing quality and safety and cardiometabolic risk factors or CVD. Understanding how the impact of housing quality on mental health, respiratory health, and developmental and cognitive outcomes extends to affecting cardiovascular health would be of utmost importance to address housing quality as a social determinant of cardiovascular health.

Housing Affordability and Accessibility

Several structural factors, including residential segregation, gentrification, and the recent foreclosure crisis, affect cardiovascular health by limiting access to affordable, high-quality housing. Racial residential segregation, or the systematic separation of racial and ethnic groups, may also influence CVD risk and serve as a root cause of health disparities in CVD. The occurrence of a higher proportion of one racial/ethnic group within neighborhoods is not inherently problematic; studies have shown that predominately minority urban neighborhoods are more likely to have more social support and cohesion, as well as access to some culturally specific resources and services.38 However, this may be offset by limited economic resources and access to jobs and high-quality schools, poorer access to health-enriching resources, and exposure to toxic stressors.39

The majority of the literature on residential segregation and CVD has focused on blacks and Hispanics. Among blacks, many but not all studies have shown that exposure to segregation is associated with CVD risk factor prevalence.40 However, longitudinal analyses in this area remain sparse. Higher levels of residential segregation were associated with incident CVD in black adults41 and with obesity among black women but not black men.42 Another study found that reductions in exposure to segregation over a 25-year follow-up period were associated with reductions in systolic blood pressure among black adults. Moreover, research suggests that black-white disparities in CVD risk are less pronounced in more integrated communities.43 Findings among Hispanics are more mixed, likely as a result of differences in background country, nativity, and length of time in the United States.40 Few studies have examined the impact of segregation on other racial/ethnic groups.

Gentrification is the process of revitalizing a deteriorating neighborhood through an influx of middle-class or affluent people. This process typically leads to the displacement of earlier, often poorer residents. Existing studies of gentrification and health have focused largely on the impact of gentrification on self-rated health and mental health. A national cross-sectional study of older adults found that economically vulnerable participants had better self-rated health than their counterparts living in low-income neighborhoods; there was no difference in self-rated health between economically vulnerable participants living in gentrifying neighborhoods and those living in moderate- to high-income neighborhoods.44

Two studies used data from a cross-sectional community survey in the Philadelphia metropolitan area. One study found that participants living in gentrifying neighborhoods, characterized by an increase in white residents and declines in nonwhites, were significantly more likely to report above-average self-rated stress levels than those living in neighborhoods that were not gentrifying.45 The other found that black participants living in gentrifying neighborhoods reported worse self-rated health than their black counterparts living in neighborhoods that were not gentrifying.46 A cross-sectional study using data from the California Health Interview Survey reported similar findings.47 This suggests that living in a gentrifying neighborhood may be worse for the health of vulnerable and underserved populations.

The foreclosure crisis has had a substantial impact on housing accessibility.48 At the beginning of the past decade, foreclosure rates peaked with ≈3 million homes at risk for foreclosure in a single year. The foreclosure crisis was initiated by a deregulated mortgage market and an increase in subprime mortgages. Subprime mortgages were problematic because loans often surpassed property values, federal financing supported creditors rather than lenders, and creditors were incentivized for subprime mortgages.48 The foreclosure crisis exploited vulnerable and underserved populations by targeting them with subprime loans.48,49

Multiple studies have observed an association between foreclosures and poor health. In the Massachusetts Framingham cohort, every additional foreclosure within 100 m of a participant was associated with a 1.7–mm Hg rise in systolic blood pressure.50 Residential areas at higher risk for foreclosure had higher proportions of hypertension and hypercholesterolemia than locations at lower risk for foreclosure in the Hispanic Community Health Study/Study of Latinos.51 In a study of 4 Western states, foreclosures were disproportionately associated with higher rates of myocardial infarctions and strokes among middle-aged blacks compared with other ethnic groups.52 The foreclosure crisis is also linked to worse adherence to medical treatments, increases in urgent elective visits, and worse psychological health.23 A consequence of property foreclosures is being evicted, which is likely to be experienced by vulnerable and underserved populations. Most studies on evictions and health examined mental health (stress, depression) followed by physical health conditions (hypertension, obesity) and reported that the threat of eviction (particularly during the subprime crisis) had a detrimental effect on psychological well-being.23

Providing equitable housing opportunities may improve cardiovascular health.10 Providing affordable housing has been associated with reduced Medicaid expenditures in 1 state.12 Multiple interventions such as a low-income housing tax credit and inclusionary zoning require further study to address the potential impact on cardiovascular health.12

Neighborhood Physical and Social Environment

Another important dimension of housing is a consideration of the broader neighborhood context in which individuals and homes exist. Neighborhood environments have emerged as strong predictors of cardiovascular health and well-being.2,53 The most robust evidence linking neighborhood environments to CVD risk and outcomes is for neighborhood socioeconomic disadvantage. Studies have consistently shown that individuals residing in economically distressed neighborhoods (eg, high percentage of poverty and unemployment) have a higher incidence of CVD risk factors (eg, obesity, diabetes mellitus, and hypertension),54 CVD events (coronary heart disease, stroke),4 and CVD mortality.55

More recently, there has been a shift in focus to the investigation of how specific features of neighborhood built/physical and social environments affect CVD. Neighborhood built/physical environment captures indicators of the design and physical attributes of a neighborhood (eg, residential density, street connectivity, traffic density) and the availability of health-promoting or -impeding resources (eg, healthy food stores, recreational facilities).56 Systematic reviews have identified extensive research documenting associations between built environment indicators and cardiometabolic factors.57 The density of healthy and unhealthy food retail, walkability, and other urban design features that define obesogenic environments have consistently been associated with not only diet, physical activity, and body mass index/obesity but also blood pressure, diabetes mellitus, and metabolic syndrome. Fewer studies have linked these features to hard CVD outcomes, and among these studies, associations between traffic-related exposures and incident coronary heart disease have been documented.58 Research also suggests that greenness or level of vegetative presence in a neighborhood may be protective for cardiovascular health. Recent studies have shown that higher levels of neighborhood greenness are associated with a lower incidence of type 2 diabetes mellitus, acute myocardial infarction, ischemic heart disease, and heart failure.59

The social environment, including the social processes, conditions, and relationships within a neighborhood, may also affect CVD.56 One study found that lower police-reported crime and higher overall neighborhood safety are associated with a lower incidence of obesity (along with average body mass index over time).60 Studies have also shown that neighborhood social cohesion is protective against incident diabetes mellitus and stroke mortality.61,62

Given the strong evidence from observational studies for the link between neighborhood socioeconomic, built/physical, and social environments and CVD, there is a need for evaluation of interventions, programs, and policies designed to improve health to determine whether those improvements also improve cardiovascular outcomes. Only 1 randomized trial, the Moving to Opportunities Study, has investigated the long-term benefits of moving people out of disadvantaged neighborhoods and showed some improvements for cardiometabolic outcomes.63 Other quasi-experimental studies that have focused on evaluating improvements in the food environment and walkability of the neighborhood have found modest to no effects on diet, physical activity, and obesity.64,65 More research is needed to better understand the levers of neighborhood change and which levers are most important for improving cardiovascular health.

Conclusions

Housing is a major social determinant of cardiovascular health and well-being. This statement summarizes research that highlights important pathways by which dimensions of housing affect cardiovascular health and general well-being. This statement also shows that there are gaps in the scientific literature on housing and health and identifies areas that need further exploration (Table). Studies have examined primarily the associations between residential economic environments and CVD risk and general health. However, few studies have examined the extent to which important dimensions of housing (stability, quality and safety, affordability and accessibility, and neighborhood social and built environment) contribute to cardiovascular health or increased cardiovascular risk that shape inequities among racial/ethnic and socioeconomic groups. This domain of SDHs emphasizes the interplay of structural, social, economic, and psychosocial factors and their impact on the association of housing with health.

Table. Research Gaps and Considerations for Housing and Health

Housing Construct Research Gaps or Considerations
Stability Increase efforts to measure primary and secondary CVD prevention and management in homeless populations
Add questions on housing insecurity to health studies
Quality and safety Examine whether and how housing deterioration (structural features) affects cardiovascular outcomes
Examine whether interventions that improve indoor air quality and energy efficiency affect cardiometabolic risk factors and CVD
Affordability and accessibility Continue efforts to understand the impact of gentrification on CVD
Evaluate cardiovascular health impacts of interventions designed to increase housing affordability and accessibility
Neighborhood environment Use quasi-experimental designs to evaluate cardiovascular impacts of interventions, programs, and policies designed to improve neighborhood conditions
Examine how changes in neighborhood environments affect changes in cardiovascular health over time
All Design interventions that address multiple features of housing
Develop comparative studies that consider health implications of housing for urban and rural residents

This area of research informs us of the importance of each pathway in addressing health inequities. We have shown that people who experience housing instability have poorer physical and mental health outcomes than those who do not. In terms of the quality and safety pathway, we have shown that numerous physical housing qualities are related to poor health. In the affordability and accessibility pathway, we have shown that families who experience foreclosures and other structural barriers limiting access to affordable housing have poorer cardiovascular and self-rated health. Finally, for the neighborhood environment pathway, we have reported that favorable built environment resources are protective of CVD and correlated with favorable health outcomes. Although each of the 4 pathways is presented as mutually exclusive factors that independently affect cardiovascular health and well-being, we acknowledge that these 4 pathways may potentially overlap and thus have a combined impact that negatively affects cardiovascular health and well-being. We also acknowledge that housing factors may also overlap with other SDHs and have a synergistic impact on health. Future work that examines the cardiovascular health effects that derive from the overlap and synergistic effects between dimensions of housing and between housing and other SDHs is warranted.

The Table displays specific research gaps and considerations that should be considered in the area of housing and health. For example, there is a need for intervention and prevention efforts that consider each housing construct but also efforts that consider combined features of each construct that will help to improve cardiovascular health inequities. Moreover, novel methods should be developed that capture areas of housing that have not been considered in research on housing as a SDH. A final consideration is that there is a need for research focused on rural housing and health, as well as urban housing and health.

Although the majority of research we reviewed on housing and cardiovascular health and well-being focuses on urban areas, these issues plague many rural places as well. Housing tends to cost less in rural communities, but poverty rates are higher and more persistent, and access to mortgage credit is more limited, leaving many families struggling to pay for housing.26 In addition, although improvements have been made in recent decades, rural low-income families often live in substandard conditions, homes with rodent problems, leaking roofs, and inadequate plumbing and heating.66 As with urban families, these factors increase the risk of homelessness in low-income rural families.15 Given this brief snapshot of rural housing-health findings, it is clear that more comparative studies are needed that consider the cardiovascular health implications of housing for urban and rural residents (Table). Harrington et al67 provide a more comprehensive review of the cardiovascular health implications of living in rural areas in the recently published American Heart Association presidential advisory on rural health.

This statement has demonstrated that housing is an important SDH. Although the theoretical framework for this statement focuses on the segment of the SDH conceptual model that addresses the pathway between housing conditions and cardiovascular health, we recognize that housing conditions may be a direct driver of cardiovascular health and well-being, as well as being intermediate in the pathway between upstream social and economic disadvantages and downstream cardiovascular health outcomes. Efforts to reduce and eliminate health disparities should promote and consider multilevel housing interventions, particularly for vulnerable and underserved populations. Efforts should also be made to consider prevention efforts that promote optimal housing conditions, which in turn contribute to ideal cardiovascular health outcomes. An understanding of these and other dimensions of housing is important for the key stakeholders (health care, community development corporations, private businesses, government) to formulate partnerships that would help to improve housing conditions in the United States, which will reduce and ultimately eliminate health inequities in housing. Finally, engaging in public policy through voting and advocacy, community networking, and population education will be integral in stabilizing the housing crisis.

Footnotes

The American Heart Association makes every effort to avoid any actual or potential conflicts of interest that may arise as a result of an outside relationship or a personal, professional, or business interest of a member of the writing panel. Specifically, all members of the writing group are required to complete and submit a Disclosure Questionnaire showing all such relationships that might be perceived as real or potential conflicts of interest.

This statement was approved by the American Heart Association Science Advisory and Coordinating Committee on May 6, 2020, and the American Heart Association Executive Committee on June 22, 2020. A copy of the document is available at https://professional.heart.org/statements by using either “Search for Guidelines & Statements” or the “Browse by Topic” area. To purchase additional reprints, call 215-356-2721 or email .

The American Heart Association requests that this document be cited as follows: Sims M, Kershaw KN, Breathett K, Jackson EA, Lewis LM, Mujahid MS, Suglia SF; on behalf of the American Heart Association Council on Epidemiology and Prevention and Council on Quality of Care and Outcomes Research. Importance of housing and cardiovascular health and well-being: a scientific statement from the American Heart Association. Circ Cardiovasc Qual Outcomes. 2020;13:e000089. doi: 10.1161/HCQ.0000000000000089

The expert peer review of AHA-commissioned documents (eg, scientific statements, clinical practice guidelines, systematic reviews) is conducted by the AHA Office of Science Operations. For more on AHA statements and guidelines development, visit https://professional.heart.org/statements. Select the “Guidelines & Statements” drop-down menu, then click “Publication Development.”

Permissions: Multiple copies, modification, alteration, enhancement, and/or distribution of this document are not permitted without the express permission of the American Heart Association. Instructions for obtaining permission are located at https://www.heart.org/permissions. A link to the “Copyright Permissions Request Form” appears in the second paragraph (https://www.heart.org/en/about-us/statements-and-policies/copyright-request-form).

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